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2020 Top

623.	Chen, H. Y., Sauer, K., Quanming Lu, X. L. Gao, and S. J. Wang, Two-band whistler-mode waves excited by an electron bi-Maxwellian distribution plus parallel beams, AIP Advances, 10, 125010, 2020.

622.	Huang, K., Quanming Lu, R. S. Wang, and S. Wang, Spontaneous growth of the reconnection electric field during magnetic reconnection with a guide field: A theoretical model and particle-in-cell simulations, Chinese Phyiscs B, 29, 075202, 2020.

621.	Guo, Jingnan, Robert F. Wimmer-Schweingruber, Mateja Dumbovic, Bernd Heber, and Yuming Wang, A new model describing Forbush Decreases at Mars: combining the heliospheric modulation and the atmospheric influence, EPP, 4, 1-11, 2020.

620.	Wang, Yuming, Xianzhe Jia, Chuanbing Wang, Shui Wang, and V. Krupar, Locating the Source Field Lines of Jovian Decametric Radio Emissions, Earth and Planetary Physics, 4, 95-104, doi: 10.26464/epp2020015, 2020. (Cover story)

619.	Liu, Kai#, XinJun Hao#, YiRen Li#, TieLong Zhang, ZongHao Pan, ManMing Chen, XiaoWen Hu, Xin Li, ChengLong Shen, and YuMing Wang, Mars Orbiter Magnetometer of China’s First Mars Mission Tianwen-1, Earth and Planetary Physics, , doi:10.26464/epp2020058, 2020.

618.	Dai, L., C. Wang, Z. M. Cai, W. Gonzalez, M. Hesse, P. Escoubet, T. Phan, V. Vasyliunas, Quanming Lu, L. Li, L. G. Kong, M. Dunlop, R. Nakamura, J. S. He, H. S. Fu, M. Zhou, S. Y. Huang, R. S. Wang, Y. Khotyaintsev, D. Graham, A. Retino, L. Zelenyi, E. E. Grigorenko, A. Runov, V. Angelopoulos, L. Kepko, K. J. Hwang, and Y. C. Zhang, , Frontiers in Physics, 8, 89, 2020.

617.	Wang, Yuming, Haisheng Ji, Yamin Wang, Lidong Xia, Chenglong Shen, Jingnan Guo, Quanhao Zhang, Zhenghua Huang, Kai Liu, Xiaolei Li, Rui Liu, Jingxiu Wang, and Shui Wang, Concept of the Solar Ring Mission: An Overview, Science China Technological Sciences*, , doi:10.1007/s11431-020-1603-2, arXiv:2003.12728, 2020.

616.	Wang, Yamin, Xin Chen, Pengcheng Wang, Chengbo Qiu, Yuming Wang, and Yonghe Zhang, Concept of the Solar Ring Mission: Preliminary Design and Mission Profile, Science China Technological Sciences, , doi:10.1007/s11431-020-1612-y, 2020.

615.	Lyu, Shaoyu, Xiaolei Li, and Yuming Wang, Optimal Stereoscopic Angle for Reconstructing Solar Wind Inhomogeneous Structures, Adv. Space Res., , doi:10.1016/j.asr.2020.07.045, arXiv:2005.06838, 2020.

614.	Joshi, Reetika, Yuming Wang, Ramesh Chandra, Quanhao Zhang, Lijuan Liu, and Xiaolei Li, Cause and Kinematics of a Jetlike CME, Astrophys. J., 901, 94(8pp), 2020.

613.	Zhuang, Bin, Noe Lugaz, Tingyu Gou, Liuguan Ding, and Yuming Wang, The Role of Successive and Interacting CMEs in the Acceleration and Release of Solar Energetic Particles: Multi-viewpoint Observations, Astrophys. J., 901, 45(14pp), 2020.

612.	He, Yuwei, Rui Liu, Lijuan Liu, Jun Chen, Wensi Wang, and Yuming Wang, Electric Currents through J-shaped and Non-J-shaped Flare Ribbons, Astrophys. J., 900, 38(11pp), 2020.

611.	Cheng, Long, Quanhao Zhang, Yuming Wang, Xiaolei Li, and Rui Liu, Using Stereoscopic Observations of Cometary Plasma Tails to Infer Solar Wind Speed, Astrophys. J., 897, 87(10pp), 2020.
Abstract.

610.	Zhang, M., R. S. Wang, Quanming Lu, and S. Wang, Observation of the tailward electron flows commonly detected at the flow boundary of the earthward ion bursty bulk flows in the magnetotail, Astrophys. J., 891, 175, 2020.

609.	Zhou, Zhenjun, Rui Liu, Xing Cheng, Chaowei Jiang, Yuming Wang, Lijuan Liu, and Jun Cui, The Relationship between Chirality, Sense of Rotation, and Hemispheric Preference of Solar Eruptive Filaments, Astrophys. J., 891, 180(6pp), 2020.

608.	Chen, Jun, Rui Liu, Kai Liu, Arun Kumar Awasthi, Peijin Zhang, Yuming Wang, and Bernhard Kliem, Extreme Ultraviolet Late Phase of Solar Flares, Astrophys. J., 890, 158, 2020.

607.	Shan, L. C., B. S. Tsurutani, Y. Ohsawa, C. Mazelle, C. Huang, A. M. Du, Y. S. Ge, and Quanming Lu, Observational Evidence for Fast Mode Periodic Small-scale Shocks: A New Type of Plasma Phenomenon, Astrophys. J. Lett., 905, L4, 2020.

606.	Xu, Zigong, Jingnan Guo, Robert F. Wimmer-Schweingruber, Johan L. Freiherr von Forstner, Yuming Wang, Nina Dresing, Henning Lohf, Shenyi Zhang, Bernd Heber, and Mei Yang, First Solar Energetic Particles Measured on the Lunar Far-side, Astrophys. J. Lett., 902, L30(8pp), 2020.

605.	Yang, Z. W., Y. D. Liu, S. Matsukiyo, Quanming Lu, F. Guo, M. Z. Liu, H. S. Xie, X. L. Gao, and J. Guo, PIC simulations of microinstabilities and plasma waves at near-Sun solar wind perpendicular shocks: Predictions of Parker Solar Probe and Solar Orbiter, Astrophys. J. Lett., 900, L24, 2020.

604.	Gou, Tingyu, Astrid M. Veronig, Rui Liu, Bin Zhuang, Mateja Dumbovic, Tatiana Podladchikova, Hamish A. S. Reid, Manuela Temmer, Karin Dissauer, Bojan Vrsnak, and Yuming Wang, Solar Flare-CME Coupling Throughout Two Acceleration Phases of a Fast CME, Astrophys. J. Lett., 897, L36(9pp), 2020.

603.	Liu, D. K., S. Lu, Quanming Lu, W. X. Ding, and S. Wang, Spontaneous Onset of Collisionless Magnetic Reconnection on Electron Scale, Astrophys. J. Lett., 890, L15, 2020.

602.	Shan, L. C., A. M. Du, Bruce T. Tsurutani, Y. S. Ge, Quanming Lu, C. Huang, C. Mazelle, K. H. Glassmeier, and P. Henr, In situ observations of the formation of periodic collisionless plasma shocks from fast mode waves, Astrophys. J. Lett., 888, L17, 2020.

601.	Quanming Lu, H. Y. Wang, X. Y. Wang, S. Lu, R. S. Wang, X. L. Gao, and S. Wang, Turbulence-driven magnetic reconnection in the magnetosheath downstream of a quasi-parallel shock：a three-dimensional global hybrid simulation, Geophys. Res. Lett., 47, e2019GL085661, 2020.

600.	Huang, K., Y. H. Liu, Quanming Lu, and M. Hesse, Scaling of magnetic reconnection with a limited x-line extent, Geophys. Res. Lett., 47, e2020GL088147, 2020.

599.	Chen, H. Y, X. L. Gao, Quanming Lu, B. Tsurutani, and S. Wang, Statistical Evidence for EMIC wave Excitation Driven by Substorm Injection and Enhanced Solar Wind Pressure in the Earth's Magnetosphere: Two different EMIC wave Sources, Geophys. Res. Lett., 47, e2020GL090275, 2020.

598.	Wang, R. S., Quanming Lu, S. Lu, C. Russell, J. Burch, D. Gershman, W. Gonzalez, and S. wang, Physical implication of two types of reconnection electron diffusion regions with and without ion-coupling in the magnetotail current sheet, Geophys. Res. Lett., 47, e2020GL088761, 2020.

597.	Liu, N. G., Su, Z. P., Gao, Z. L., Zheng, H. N., Wang, Y. M., Wang, S., Miyoshi, Y., Shinohara, I., Kasahara, Y., Tsuchiya, F., Kumamoto, A., Matsuda, S., Shoji, M., Mitani, T., Takashima, T., Kazama, Y., Wang, B.-J., Wang, S.-Y., Jun, C.-W., Chang, T.-F., Tam, Sunny W. Y., Kasahara, S., Yokota, S., Keika, K., Hori, T., and Matsuoka, A., Comprehensive observations of substorm-enhanced plasmaspheric hiss generation, propagation, and dissipation, Geophys. Res. Lett.*, 47, e2019GL086040, 2020.

596.	Liu, N. G., Su, Z. P., Gao, Z. L., Zheng, H. N., Wang, Y. M., and Wang, S., Can solar wind decompressive discontinuities suppress magnetospheric electromagnetic ion cyclotron waves associated with fresh proton injections?, Geophys. Res. Lett.*, 47, e2020GL090296, 2020.

595.	Wang, Z. S., Su, Z. P., Liu, N. G., Dai, G. Y., Zheng, H. N., Wang, Y. M., and Wang, S., Suprathermal electron evolution under the competition between plasmaspheric plume hiss wave heating and collisional cooling, Geophys. Res. Lett., 47, e2020GL089649, 2020.

594.	Su, Z. P., Liu, N. G., Gao, Z. L., Zheng, H. N., Wang, Y. M., and Wang, S., Rapid Landau heating of Martian topside ionospheric electrons by large-amplitude magnetosonic waves, Geophys. Res. Lett.*, 47, e2020GL090190, 2020.

593.	Liu, Nigang, Zhenpeng Su, Zhonglei Gao, Huinan Zheng, Yuming Wang, Shui Wang, Yoshizumi Miyoshi, Iku Shinohara, Yoshiya Kasahara, Fuminori Tsuchiya, Atsushi Kumamoto, Shoya Matsuda, Masafumi Shoji, Takefumi Mitani, Takeshi Takashima, Yoichi Kazama, Bo-Jhou Wang, Shiang-Yu Wang, Chae-Woo Jun, Tzu-Fang Chang, Sunny W. Y. Tam, Satoshi Kasahara, Shoichiro Yokota, Kunihiro Keika, Tomoaki Hori, and Ayako Matsuoka, Comprehensive Observations of Substorm-Enhanced Plasmaspheric Hiss Generation, Propagation, and Dissipation, Geophys. Res. Lett., 47, e2019GL086040, 2020.

592.	Liu, Nigang, Zhenpeng Su, Zhonglei Gao, Huinan Zheng, Yuming Wang, and ShuiWang, Can solar wind decompressive discontinuities suppress magnetospheric electromagnetic ion cyclotron waves associated with fresh proton injections?, Geophys. Res. Lett.*, 47, doi:10.1029/2020GL090296, 2020.

591.	Wang, Zhongshan, Zhenpeng Su, Nigang Liu, Guyue Dai, Huinan Zheng, Yuming Wang, and Shui Wang, Suprathermal Electron Evolution Under the Competition Between Plasmaspheric Plume Hiss Wave Heating and Collisional Cooling, Geophys. Res. Lett., 47, e2020GL089649, 2020.

590.	Su, Zhenpeng, Nigang Liu, Zhonglei Gao, Bin Wang, Huinan Zheng, Yuming Wang, and Shui Wang, , Geophys. Res. Lett., 47, e2020GL090190, doi:10.1029/2020GL090190, 2020.

589.	Hui Zhu, Lunjin Chen, and Zhiyang Xia, Electron driven by Magnetic Dip Embedded Within the Proton driven by Magnetic Dip and the Related Echoes of Butterfly Distribution of Relativistic Electrons, Geophys. Res. Lett., , 2020.

588.	Ke, Y. G., Quanming Lu, X. L. Gao, X. Y. Wang, L. J. Chen, S. J. Wang, and S. Wang, Particle-in-cell simulations of characteristics of rising-tone chorus waves in the inner magnetosphere, J. Geophys. Res. - Space Phys., 125, e2020JA027961, 2020.

587.	Tsurutani, B., L. Chen, X. L. Gao, Quanming Lu, J. Pickett, G. Lakhina, A. Sen, R. Hajra, S. Park, and B. Falkowski, Lower-Band "Monochromatic" Chorus Riser Subelement/Wave Packet Observations, J. Geophys. Res. - Space Phys., 125, e2020JA028090, 2020.

586.	Li, Xiaolei, Yuming Wang, Rui Liu, Chenglong Shen, Quanhao Zhang, Shaoyu Lyu, Bin Zhuang, Fang Shen, Jiajia Liu, and Yutian Chi, Reconstructing solar wind inhomogeneous structures from stereoscopic observations in white-light: Solar wind transients in 3D, J. Geophys. Res. - Space Phys.*, , doi:10.1029/2019JA027513, 2020.

585.	Quanming Lu, R. S. Wang, K. Huang, and S. Wang, Magnetic islands in collisionless magnetic reconnection, J. Univ. of Sci. & Tech. of China, 50, 1218, 2020.

584.	Raghav, Anil, Sandesh Gaikwad, Yuming Wang, Zubair I. Shaikh, Wageesh Mishra, and Ake Zao, Study of flux rope characteristics at sub-astronomical-unit distances using the Helios 1 and 2 spacecraft, Mon. Not. R. Astron. Soc., 495, 1566-1576, doi:10.1093/mnras/staa1189, 2020.

583.	Wang, S. M., R. S. Wang, Quanming Lu, H. S. Fu, and S. Wang, Direct evidence of secondary reconnection inside filamentary currents of magnetic flux ropes in magnetic reconnection, Nat. Comm., 11, 3964, 2020.

582.	Lu, S., R. S.Wang, Quanming Lu, V. Angelopoulos, R. Nakamura, A. Artemyev, P. Pritchett, T. Liu, X. J. Zhang, W. Baumjohann, W. Gonzalez, A. Rager, R. Torbert, B. Giles, D. Gershman, C. Russell, R. Strangeway, Y. Qi, R. Ergun, P.-A. Lindqvist, J. Burch, and S. Wang, Magnetotail reconnection onset caused by electron kinetics with a strong external driver, Nat. Comm., 11, 5049, 2020.

581.	Yao, J. S., Quanming Lu, X. L. Gao, J. Zheng, H. Y. Chen, Y. Li, and S. Wang, Generation of Harmonic Alfvén Waves and Its Implications to Heavy Ion Heating in the Solar Corona: Hybrid Simulations, Phys. Plasmas, 27, 012901, 2020.

2019 Top

580.	Abid, A. A., Quanming Lu, M. N. S. Qureshi, X. L. Gao, H. Y. Chen, K. H. Shah, and S. Wang, 1-D particle-in-cell simulations of electron acoustic solitary structures in an electron beam-plasma, AIP Advances, 9, 025029, 2019.

579.	Liu, Jiajia, Yuming Wang, and Robert Erdelyi, How Many Twists Do Solar Coronal Jets Release?, Frontiers in Astronomy and Space Sciences, 6, 44, 2019.

578.	Shi, P. Y., K. Huang, Quanming Lu, and X. Sun, Experimental Observation of Kinetic Alfvén Wave Generated by Magnetic Reconnection, Plasma Physics and Controlled Fusion, 61, 125010, 2019.

577.	Abid, A. A., Quanming Lu, H. Y. Chen, Y. G. Ke, S. Ali, and S. Wang, Effects of electron trapping on nonlinear electron-acoustic waves excited by an electron beam via particle-in-cell simulations, Plasma Sci. Technol., 21, 055301, 2019.

576.	Hu, R. X., Shan, X., Yuan, G. Y., Wang, S. W., Zhang, W. H., Qi, W., Cao, Z., Li, Y. R., Chen, M. M., Yang, X. P., Wang, B., Shao, S. P., Li, F., Zhong, X. Q., Fan, D., Hao, X. J., Feng, C. Q., Su Z. P., Shen, C. L., Li, X., Dai, G. Y., Qiu, B. L., Pan, Z. H., Liu, K., Xu, C. K., Liu, S. B., An, Q., Zhang, T. L., Wang, Y. M., and Chen, X. J., A low-energy ion spectrometer with half-space entrance for three-axis stabilized spacecraft, Sci. China Tech. Sci.*, 62, 1015-1027, 2019.

575.	Gou, Tingyu, Rui Liu, Bernhard Kliem, Yuming Wang, and Astrid M. Veronig, The birth of a coronal mass ejection, Science Advances, 5, eaau7004, 2019.

574.	HU RenXiang, SHAN Xu, YUAN GuangYuan, WANG ShuWen, ZHANG WeiHang, QI Wei, CAO Zhe, LI YiRen, CHEN ManMing, YANG XiaoPing, WANG Bo, SHAO SiPei, HAO XinJun, FENG ChangQing, SU ZhenPeng, SHEN ChengLong, LI Xin, DAI GuYue, QIU BingLin, PAN ZongHao, LIU Kai, XU ChunKai, LIU ShuBin, AN Qi, ZHANG TieLong, WANG YuMing, and CHEN XiangJun, A low-energy ion spectrometer with half-space entrance for three-axis stabilized spacecraft, Science China Technological Sciences, 62, 1015-1027, doi:10.1007/s11431-018-9288-8, 2019.
Abstract.

573.	Sun, J. C., X. L. Gao, Y. G. Ke, Quanming Lu, X. Y. Wang, and S. Wang, Expansion of Hot Coronal Electrons in an Inhomogeneous Magnetic Field: 1-D PIC Simulation, Astrophys. J., 887, 96, 2019.

572.	Xu, Mengjiao, Chenglong Shen, Yutian Chi, Yuming Wang, Qiang Hu, Gang Li, Zhihui Zhong, and Jiayi Liu, The Enhancement of the Energetic Particle Intensities in ICMEs, Astrophys. J., 885*, 54(12pp), 2019.

571.	Zhao, Ake, Yuming Wang, Hengqiang Feng, Bin Zhuang, Xiaolei Li, Hongbo Li, and Hong Jia, The Relationship of Magnetic Twist and Plasma Motion in a Magnetic Cloud, Astrophys. J., 885, 122(5pp), 2019.

570.	Liu, Lijuan, Xin Cheng, Yuming Wang, and Zhenjun Zhou, Formation of a Magnetic Flux Rope in the early emergence phase of NOAA active region 12673, Astrophys. J., 884, 45(17pp), 2019.

569.	Sang, L. L., Quanming Lu, R. S. Wang, K. Huang, and S. Wang, A parametric study of the structure of Hall magnetic field based on kinetic simulations. II. Asymmetric magnetic reconnection with a guide field, Astrophys. J., 882, 126, 2019.

568.	Dumbovic, Mateja, Jingnan Guo, Manuela Temmer, M. Leila Mays, Astrid Veronig, Stephan Heinemann, Karin Dissauer, Stefan Hofmeister, Jasper Halekas, Christian Mostl, Tanja Amerstorfer, Jurgen Hinterreiter, Sasa Banjac, Konstantin Herbst, Yuming Wang, Lukas Holzknecht, Martin Leitner, and , Unusual plasma and particle signatures at Mars and STEREO-A related to CME-CME interaction, Astrophys. J., 880, 18(16pp), 2019.

567.	Zhuo, Zhenjun, Xin Cheng, Lijuan Liu, Yu Dai, Yuming Wang, and Jun Cui, Extreme-ultraviolet Late Phase Caused by Magnetic Reconnection over Quadrupolar Magnetic Configuration in a Solar Flare, Astrophys. J., 878, 46(11pp), 2019.
Abstract.

566.	Sang, L. L., Quanming Lu, R. S. Wang, K. Huang, and S. Wang, A parametric study on the structure of Hall magnetic field based on kinetic simulations. I. Anti-parallel magnetic reconnection in an asymmetric current sheet, Astrophys. J., 877, 155, 2019.

565.	Zhuang, Bin, Yuming Wang, Youqiu Hu, Chenglong Shen, Rui Liu, Tingyu Gou, Quanhao Zhang, and Xiaolei Li, Numerical simulations on the deflection of coronal mass ejections in the interplanetary, Astrophys. J., 876, 73(12pp), 2019.

564.	Zhuang, Bin, Yuming Wang, Youqiu Hu, Chenglong Shen, Rui Liu, Tingyu Gou, Quanhao Zhang, and Xiaolei Li, Numerical simulations on the deflection of coronal mass ejections in the interplanetary space, Astrophys. J., 876, 73(12pp), 2019.
Abstract. Deflection of coronal mass ejections (CMEs) in the interplanetary space, especially in the ecliptic plane, serves as an important factor deciding whether CMEs arrive at the Earth. Observational studies have shown evidence for deflection, whose detailed dynamic processes, however, remain obscure. Here we developed a 2.5D ideal magnetohydrodynamic simulation to study the propagation of CMEs traveling with different speeds in the heliospheric equatorial plane. The simulation confirms the existence of the CME deflection in the interplanetary space, which is related to the difference between the CME speed (vr) and the solar wind speed (vsw): a CME will propagate radially as vr is close to vsw but eastward or westward when vr is larger or smaller than vsw; the greater the difference is, the larger the deflection angle will be. This result supports the model for CME deflection in the interplanetary space (DIPS) proposed by Wang et al., predicting that an isolated CME can be deflected due to the pileup of solar wind plasma ahead of or behind the CME. Furthermore, the deflection angles, which are derived by inputting vr and vsw from the simulation into the DIPS model, are found to be consistent with those in the simulation. This work was supported the grants from NSFC (41774178, 41574165, 41274173, and 41804161), and the fundamental research funds for the central universities. We also acknowledge funds from Key Laboratory of Space Weather, National Center for Space Weather, China Meteorological Administration.

563.	Cheng, Zhixun, Yuming Wang, Rui Liu, Zhenjun Zhou, and Kai Liu, Plasma Motion inside Flaring Regions Revealed by Doppler Shift Information from SDO/EVE Observations, Astrophys. J., 875*, 93(14pp), 2019.
Abstract.

562.	Awasthi, Arun Kumar, Rui Liu, and Yuming Wang, Double-decker Filament Configuration Revealed by Mass Motions, Astrophys. J., 872, 109(11pp), 2019. (AAS NOVA Highlight https://aasnova.org/2019/04/17/exploring-filaments-on-the-sun/)
Abstract. It is often envisaged that dense filament material lies in the dips of magnetic field lines belonging to either a sheared arcade or a magnetic flux rope. But it is also debated which configuration correctly depicts filaments’ magnetic structure, due to our incapacity to measure the coronal magnetic field. In this paper, we address this issue by employing mass motions in an active-region filament to diagnose its magnetic structure. The disturbance in the filament was driven by a surge initiated at the filament’s eastern end in the NOAA active region 12685, which was observed by the 1 m New Vacuum Solar Telescope in the Hα line-center and line wing (±0.4 Å). Filament material predominately exhibits two kinds of motions, namely, rotation about the spine and longitudinal oscillation along the spine. The former is evidenced by antisymmetric Doppler shifts about the spine; the latter features a dynamic barb with mass extending away from the Hα spine until the transversal edge of the EUV filament channel. The longitudinal oscillation in the eastern section of the filament is distinct from that in the west, implying that the underlying field lines have different lengths and curvature radii. The composite motions of filament material suggest a double-decker host structure with mixed signs of helicity, comprising a flux rope atop a sheared-arcade system. A.K.A. acknowledges the support from the Chinese Academy of Science (CAS) as well as the International Postdoctoral Program of University of Science and Technology of China. R.L. acknowledges the support from NSFC 41474151, 41774150, and 41761134088. This investigation made use of the data acquired from NVST, which is operated by Yunnan Astronomical Observatory, China. A.K.A. acknowledges the hospitality offered by the staff of Fuxian Solar Observatory during his stay for the observing period and Dr. Y. Y. Xiang for helping with the alignment of NVST images. The authors also acknowledge the free data usage policy of SDO, GOES, and GONG Hα network. Software: MPFIT (Markwardt 2009).

561.	Xu, Mengjiao, Chenglong Shen, Yuming Wang, Bingxian Luo, and Yutian Chi, Importance of Shock Compression in Enhancing ICME’s Geoeffectiveness, Astrophys. J. Lett., 884, L30(7pp), 2019.

560.	Guo, Jingnan, Robert Wimmer-Schweingruber, Yuming Wang, Manuel Grande, Daniel Matthia, Cary Zeitlin, Bent Ehresmann, and Donald M. Hassler, The pivot energy of solar energetic particles affecting the Martian surface radiation environment, Astrophys. J. Lett., 883, L12(8pp), 2019.

559.	Zhou, Zhenjun, Xin Cheng, Jie Zhang, Yuming Wang, Dong Wang, Lijuan Liu, Bin Zhuang, and Jun Cui, Why do torus-unstable solar filaments experience failed eruptions?, Astrophys. J. Lett., 877, L28(6pp), 2019.
Abstract.

558.	Liu, Y, Quanming Lu, R. S. Wang, K. Huang, H. Y. Wang, and S. Wang, Electron acceleration and formation of power-law spectra of energetic electrons during the merging process of multiple magnetic islands: particle-in-cell simulations, Astrophys. & Space Sci., 364, 109, 2019.

557.	Sun, J. C., X. L. Gao, Quanming Lu, and S. Wang, Dissipation and reformation of thermal fronts in solar flares, Astrophys. & Space Sci., 364, 116, 2019.

556.	Gao, X. L., L. J. Chen, W. Li, Quanming Lu, and S. Wang, Statistical results of the power gap between lower-band and upper-band chorus waves, Geophys. Res. Lett., 46, 4098-4105, 2019.

555.	Yu, X. C., R. S. Wang, Quanming Lu, C. T. Russell, and S. Wang, The Non-ideal Electric Field Observed in the Separatrix Region of a Magnetotail Reconnection Event, Geophys. Res. Lett., 46, 10744-10753, 2019.

554.	Chen, R., X. L. Gao, Quanming Lu, and S. Wang, Unraveling the Correlation between Chorus Wave and Electron Beam-like Distribution in the Earth's Magnetosphere, Geophys. Res. Lett., 46, 11671-11678, 2019.

553.	Li, X. M., R. S. Wang, Quanming Lu, K. J. Hwang, Q. G. Zong, C. Russell, and S. Wang, Observation of non-gyrotropic electron distribution across the electron diffusion region in the magnetotail reconnection, Geophys. Res. Lett., 46, 14263-14273, 2019.

552.	Liu, N. G., Su, Z. P., Gao, Z. L., Zheng, H. N., Wang, Y. M., and Wang, S., Magnetospheric chorus, exohiss, and magnetosonic emissions simultaneously modulated by fundamental toroidal standing Alfvén waves following solar wind dynamic pressure fluctuations, Geophys. Res. Lett.*, 46, 1900-1910, 2019.

551.	Dai, G. Y., Su, Z. P., Liu, N. G., Wang, B., Zheng, H. N., Wang, Y. M., and Wang, S., Quenching of equatorial magnetosonic waves by substorm proton injections, Geophys. Res. Lett.*, 46, 6156-6167, 2019.

550.	Dai, Guyue, Zhenpeng Su, Nigang Liu, Bin Wang, Huinan Zheng, YumingWang, and ShuiWang, Quenching of Equatorial Magnetosonic Waves by Substorm Proton Injections, Geophys. Res. Lett., 46, 6156-6167, 2019.

549.	Hui Zhu, Xu Liu, and Lunjin Chen, Triggered Plasmaspheric Hiss: Rising Tone Structures, Geophys. Res. Lett., , 2019.

548.	Lunjin Chen, Hui Zhu, and Xiaojia Zhang, Wavenumber analysis of EMIC waves, Geophys. Res. Lett., , 2019.

547.	Hui Zhu, and Lunjin Chen, On the Observation of Electrostatic Harmonics Associated With EMIC Waves, Geophys. Res. Lett., , 2019.

546.	Hui Zhu, Lunjin Chen, Seth G. Claudepierre, and Liheng Zheng, Direct Evidence of the Pitch Angle Scattering of Relativistic Electrons Induced by EMIC Waves, Geophys. Res. Lett., , 2019.

545.	Hui Zhu, Yuri Y. Shprits, M. Spasojevic, and Alexander Y. Drozdov, New hiss and chorus waves diffusion coefficient parameterizations from the Van Allen Probes and their effect on long-term relativistic electron radiation-belt VERB simulations, J. Atoms. Sol.-Terres. Phys., , 2019.

544.	Wang, S. M., R. S. Wang, S. T. Yao, Quanming Lu, C. T. Russell, and S. Wang, Anisotropic electron distributions and whistler waves in a series of the flux transfer events at the magnetopause, J. Geophys. Res. - Space Phys., 124, 1753-1769, 2019.

543.	Fan, K., X. L. Gao, Quanming Lu, J. Guo, and S. Wang, The effects of thermal electrons on whistler mode waves excited by anisotropic hot electrons: linear theory and 2D PIC simulations, J. Geophys. Res. - Space Phys., 124, 5234-5245, 2019.

542.	Quanming Lu, Y. G. Ke, X. Y. Wang, K. J. Liu, X. L. Gao, L. J. Chen, and S. Wang, Two-dimensional general curvilinear particle-in-cell (gcPIC) simulation of rising-tone chorus waves in a dipole magnetic field, J. Geophys. Res. - Space Phys., 124, 4157-4167, 2019.

541.	Chen, H. Y., X. L. Gao, Quanming Lu, and S. Wang, Reanalyzing EMIC Waves in the Inner Magnetosphere Derived from Long-term Van Allen Probes Observations, J. Geophys. Res. - Space Phys., 124, 7402-7412, 2019.

540.	Wu, Y. F., X. Tao, Quanming Lu, and S. Wang, Saturation Properties of WhistlerWave Instability in a Plasma With Two Electron Components, J. Geophys. Res. - Space Phys., 124, 5121-5128, 2019.

539.	Hui Zhu, Lunjin Chen, Xu Liu, and Yuri Y. Shprits, Modulation of Locally Generated Equatorial Noise by ULF Wave, J. Geophys. Res. - Space Phys., , 2019.

538.	Hui Zhu, Wenyao Gu, and Lunjin Chen, Statistical analysis on plasmatrough exohiss waves from the Van Allen Probes, J. Geophys. Res. - Space Phys., , 2019.

537.	Mishra, Wageesh, Nandita Srivastava, Yuming Wang, Zavkiddin Mirtoshev, Jie Zhang, and Rui Liu, Mass Loss via Solar Wind and Coronal Mass Ejections During Solar Cycles 23 and 24, Mon. Not. R. Astron. Soc., 486, 4671-4685, 2019.

536.	Yang, Yan, Minping Wan, William H. Matthaeus, Luca Sorriso-Valvo, Tulasi N. Parashar, Quanming Lu, Yipeng Shi, and Shiyi Chen, Scale dependence of energy transfer in turbulent plasma, Mon. Not. R. Astron. Soc., 482, 4933-4940, 2019.

535.	Liu, Jiajia, Chris J. Nelson, Ben Snow, Yuming Wang, and Robert Erdélyi, Evidence of ubiquitous Alfvén pulses transporting energy from the photosphere to the upper chromosphere, Nat. Comm., 10, 3504, 2019.
Abstract. The multi-million degree temperature increase from the middle to the upper solar atmosphere is one of the most fascinating puzzles in plasma-astrophysics. Although magnetic waves might transport enough energy from the photosphere to heat up the local chromosphere and corona, observationally validating their ubiquity has proved challenging. Here, we show observational evidence that ubiquitous Alfvén pulses are excited by prevalent intensity swirls in the solar photosphere. Correlation analysis between swirls detected at different heights in the solar atmosphere, together with realistic numerical simulations, show that these Alfvén pulses propagate upwards and reach chromospheric layers. We found that Alfvén pulses carry sufficient energy flux (1.9 to 7.7 kW m−2) to balance the local upper chromospheric energy losses (~0.1 kW m−2) in quiet regions. Whether this wave energy flux is actually dissipated in the chromosphere and can lead to heating that balances the losses is still an open question. Acknowledgement: We thank the Science and Technology Facilities Council (STFC, grant numbers ST/M000826/1, ST/L006316/1) for the support to conduct this research. CJN also acknowledges support by STFC consolidated grant ST/P000304/1. YW acknowledges support by NSFC 41774178, 41574165 and 41761134088. Hinode is a Japanese mission developed and launched by ISAS/JAXA, with NAOJ as domestic partner and NASA and STFC (UK) as international partners. Hinode is operated by these agencies in co-operation with ESA and NSC (Norway). The Swedish 1-m Solar Telescope is operated on the island of La Palma by the Institute for Solar Physics of Stockholm University in the Spanish Observatorio del Roque de los Muchachos of the Instituto de Astrofísica de Canarias. The Institute for Solar Physics is supported by a grant for research infrastructures of national importance from the Swedish Research Council (registration number 2017-00625). The SST data was collected as part of the observing time proposal awarded in 2012 to RE as the PI. We thank the SOLARNET for the awarding of the observing time and the data reduction.

534.	Shi, P. Y., Z. D. Yang, M. Luo, R. S. Wang, Quanming Lu, and X. Sun, Observation of spontaneous decay of Alfvénic fluctuations into co- and counterpropagating magnetosonic waves in a laboratory plasma, Phys. Plasmas, 26, 032105, 2019.

533.	Chien, A., L. Gao, H. T. Ji, X. X. Yuan, E. G. Blackman, H. Chen, P. Efthimion, G. Fiksel, D. Froula, K. Hill, K. Huang, Quanming Lu, J. D. Moody, and P. M. Nilson, Study of a magnetically driven reconnection platform using ultrafast proton radiography, Phys. Plasmas, 26, 062113, 2019.

532.	Yang, Y., M. P. Wan, W. H. Matthaeus, Y. P. Shi, T. N. Parashar, Quanming Lu, and S. Y. Chen, Role of magnetic field curvature in magnetohydrodynamic turbulence, Phys. Plasmas, 26, 072306, 2019.

531.	Zhang, Peijin, Chuangbin Wang, Ye Lin, and Yuming Wang, Forward Modeling of the Type III Radio Burst Exciter, Sol. Phys., 294, 62(20pp), 2019.

530.	王水 and 陆全明, 无碰撞磁场重联, 科学出版社, 北京, 2019.

529.	季海生, 汪毓明, and , 太阳的立体观测, 中国科学－物理学、力学、天文学, , 2019.

2018 Top

528.	Gao, X. L., Quanming Lu, S. J. Wang, and S. Wang, Theoretical analysis on lower band cascade as a mechanism for multiband chorus in the Earth's magnetosphere, AIP Advances, 8, 055003, 2018.

527.	Teng, S. C., X. Tao, W. Li, Y. Qi, X. L. Gao, L. Dai, Quanming Lu, and S. Wang, A statistical study of the spatial distribution and source-region size of chorus waves using Van Allen Probes data, Annales Geophysicae, 36, 867-878, 2018.

526.	Gao, Z. L., Su, Z. P., Xiao, F. L., Zheng, H. N., Wang, Y. M., Wang, S., Spence, H. E., Reeves, G. D., Baker, D. N., Blake, J. B., Funsten, H. O., and Wygant, J. R., Exohiss wave enhancement following substorm electron injection in the dayside magnetosphere, Earth Planet. Phys.*, 2, 359-370, 2018.

525.	Zhuang, Bin, YuMing Wang, ChengLong Shen, and Rui Liu, A statistical study of the likelihood of a super geomagnetic storm occurring in a mild solar cycle, Earth and Planetary Physics, 2, 112-119, 2018.
Abstract.

524.	Lin, M, H. Lian, M. Liu, G. Zhu, Z. Yang, P. Shi, Quanming Lu, and X. Sun, A 7.8 kV nanosecond pulse generator with a 500 Hz repetition rate, Journal of Instrumentation, 13, P04004, 2018.

523.	Yi, H. S., M. Liu, P. Y. Shi, Z. D. Yang, G. H. Zhu, Quanming Lu, and X. Sun, Characterization of a medium-sized washer-gun for an axisymmetric mirror, Review of Scientific Intruments, 89, 043503, 2018.

522.	Zhang, Q. F., J. L. Xie, M. Luo, X. Sun, F. B. Fan, Quanming Lu, W. X. Ding, and Y. L. Zhu, Laser-induced fluorescence diagnostic via pulsed lasers in an argon plasma, Reviews of Scientific Instruments, 89, 10C119, 2018.

521.	Liu, Rui, Jun Chen, and Yuming Wang, Disintegration of an Eruptive Filament via Interactions with Quasi-Separatrix Layers, Science China: Physics, Mechanics & Astronomy, 61, 069611, 2018.
Abstract. The disintegration of solar filaments via mass drainage is a frequently observed phenomenon during a variety of filament activities. It is generally considered that the draining of dense filament material is directed by both gravity and magnetic field, yet the detailed process remains elusive. Here we report on a partial filament eruption during which filament material drains downward to the surface not only along the filament’s legs, but to a remote flare ribbon through a fan-out curtain-like structure. It is found that the magnetic configuration is characterized by two conjoining dome-like quasi-sepratrix layers (QSLs). The filament is located underneath one QSL dome, whose footprint apparently bounds the major flare ribbons resulting from the filament eruption, whereas the remote flare ribbon matches well with the other QSL dome’s far-side footprint. We suggest that the interaction of the filament with the overlying QSLs results in the splitting and disintegration of the filament. This work was supported by the National Natural Science Foundation of China (Grant Nos. 41474151, 41774150, and 41421063), the Thousand Young Talents Program of China, CAS Key Research Program of Frontier Sciences of (Grant No. QYZDB-SSW-DQC015), and the Fundamental Research Funds for the Central Universities.

520.	Liu, Rui, Yuming Wang, Jeongwoo Lee, and Chenglong Shen, Impacts of EUV Wavefronts on Coronal Structures in Homologous Coronal Mass Ejections, Astrophys. J., 870, 15(18pp), 2018.
Abstract. Large-scale propagating fronts are frequently observed during solar eruptions, yet whether or not they are waves is an open question, partly because the propagation is modulated by coronal structures, whose magnetic fields we still cannot measure. However, when a front impacts coronal structures, an opportunity arises for us to look into the magnetic properties of both interacting parties in the low-β corona. Here we studied large-scale EUV fronts accompanying three coronal mass ejections (CMEs), each originating from a kinking rope-like structure in the NOAA active region (AR) 12371. These eruptions were homologous and the surrounding coronal structures remained stationary. Hence we treated the events as one observed from three different viewing angles, and found that the primary front directly associated with the CME consistently transmits through (1) a polar coronal hole, (2) the ends of a crescent-shaped equatorial coronal hole, leaving a stationary front outlining its AR-facing boundary, and (3) two quiescent filaments, producing slow and diffuse secondary fronts. The primary front also propagates along an arcade of coronal loops and slows down due to foreshortening at the far side, where local plasma heating is indicated by an enhancement in 211Å (Fe XIV) but a dimming in 193Å (Fe XII) and 171Å (Fe IX). The strength of coronal magnetic field is therefore estimated to be ∼2G in the polar coronal hole and ∼4G in the coronal arcade neighboring the AR. These observations substantiate the wave nature of the primary front and shed new light on slow fronts. The authors thank the anonymous referee for critical comments and constructive suggestions that helped improve the manuscript. R.L. acknowledges support by NSFC 41474151, 41774150, and 41761134088. Y.W. acknowledges support by NSFC 41131065 and 41574165. J.L. was supported by the NSFC grants 41331068, 11790303 (11790300), and 41774180. This work was also supported by NSFC 41421063, CAS Key Research Program KZZD-EW-01-4, and the fundamental research funds for the central universities.

519.	Dong Wang, Rui Liu, Yuming Wang, Tingyu Gou, Quanhao Zhang, Zhenjun Zhou, and Min Zhang, Unraveling the links among sympathetic eruptions, Astrophys. J., 869, 177(10pp), 2018.
Abstract. Solar eruptions occurring at different places within a relatively short time interval are considered to be sympathetic. However, it is difficult to determine whether there exists a cause and effect between them. Here we study a failed and a successful filament eruption following an X1.8-class flare on 2014 December 20, in which slipping-like magnetic reconnections serve as a key causal link among the eruptions. Reconnection signatures and effects are identified as follows: at both sides of the filament experiencing the failed eruption, serpentine ribbons extend along the chromospheric network to move away from the filament, while a hot loop apparently grows above it; at the filament undergoing the successful eruption, overlying cold loops contract, while coronal dimming appears at both sides even before the filament eruption. These effects are understood by reconnections continually transforming magnetic fluxes overlying one filament to the other, which adjusts how the magnetic field decays with increasing height above the filaments in opposite trends, therefore either strengthening or weakening the magnetic confinement of each filament. D.W. acknowledges support by Natural Science Foundation of Anhui Province Education Department (KJ2017A493, KJ2017A491, gxyq2018030) and NSFC 11704003. R.L. acknowledges support by NSFC 41474151, 41774150, and 41761134088. Y.W. acknowledges support by NSFC 41774178 and 41574165. M.Z. acknowledges support by Natural Science Foundation of Anhui Province Education Department (KJ2016JD24) and Anhui Province Quality Engineering (2017zhkt161). This work is also supported by NSFC 41421063, CAS Key Research Program of Frontier Sciences QYZDB-SSW-DQC015, and the fundamental research funds for the central universities. Software: SolarSoftWare (Freeland & Handy 2012).

518.	Mishra, Wageesh* and Yuming Wang, Modeling the thermodynamic evolution of Coronal Mass Ejections using their kinematics, Astrophys. J., 865*, 50(15pp), 2018.
Abstract. Earlier studies on coronal mass ejections (CMEs), using remote sensing and in situ observations, have attempted to determine some internal properties of CMEs, which were limited to a certain position or a certain time. To understand the evolution of the internal thermodynamic state of CMEs during their heliospheric propagation, we improve the self-similar flux-rope internal state model, which is constrained by the measured propagation and expansion speed profiles of a CME. We implement the model in a CME that erupted on 2008 December 12 and probe the internal state of the CME. It is found that the polytropic index of the CME plasma decreased continuously from 1.8 to 1.35 as the CME moved away from the Sun, implying that the CME released heat before it reached an adiabatic state and then absorbed heat. We further estimate the entropy changing and heating rate of the CME. We also find that the thermal force inside the CME is the internal driver of CME expansion while the Lorentz force prevented the CME from expanding. It is noted that the centrifugal force due to poloidal motion decreased at the fastest rate, and the Lorentz force decreased slightly faster than the thermal pressure force as the CME moved away from the Sun. We also discuss the limitations of the model and approximations made in the study. We acknowledge the UK Solar System Data Center (UKSSDC) for providing the STEREO/COR2 data. Y.W. is supported by the National Natural Science Foundation of China (NSFC) grant Nos. 41574165, 41774178, and 41761134088. W.M. is supported by NSFC grant No. 41750110481 and the Chinese Academy of Sciences (CAS) President’s International Fellowship Initiative (PIFI) grant No. 2015PE015. W.M. thanks Ying D. Liu (CAS, China) for the helpful discussion.

517.	Chi, Yutian, Zhang, Jie, Shen, Chenglong, Hess, Phillip, Liu, Lijuan, Mishra, Wageesh, and Wang, Yuming, Observational Study of an Earth-affecting Problematic ICME from STEREO, Astrophys. J., 863, 108(13pp), 2018.
Abstract.

516.	Hao, Y. F., Quanming Lu, X. L. Gao, H. Y. Wang, D. J. Wu, and S. Wang, Two-dimensional hybrid simulations of filamentary structures and kinetic slow waves downstream of a quasi-parallel shock, Astrophys. J., 861, 57, 2018.

515.	Shen, Chenglong, Mengjiao Xu, Yuming Wang, Yutian Chi, and Bingxian Luo, Why the Shock-ICME Complex Structure Is Important: Learning from the Early 2017 September CMEs, Astrophys. J., 861, 28(9pp), 2018.
Abstract. In the early days of 2017 September, an exceptionally energetic solar active region AR 12673 aroused great interest in the solar physics community. It produced four X class flares, more than 20 coronal mass ejections (CMEs), and an intense geomagnetic storm, for which the peak value of the Dst index reached up to −142 nT at 2017 September 8 02:00 UT. In this work, we check the interplanetary and solar source of this intense geomagnetic storm. We find that this geomagnetic storm was mainly caused by a shock-interplanetary CME (ICME) complex structure, which was formed by a shock driven by the 2017 September 6 CME propagating into a previous ICME, which was the interplanetary counterpart of the 2017 September 4 CME. To better understand the role of this structure, we conduct a quantitative analysis on the enhancement of ICME’s geoeffectiveness induced by the shock compression. The analysis shows that the shock compression enhanced the intensity of this geomagnetic storm by a factor of two. Without shock compression, there would have been only a moderate geomagnetic storm with a peak Dst value of ∼−79 nT. In addition, the analysis of the proton flux signature inside the shock-ICME complex structure shows that this structure also enhanced the solar energetic particle intensity by a factor of approximately five. These findings illustrate that the shock-ICME complex structure is a very important factor in solar physics study and space weather forecast. The authors thank the referee for comments that helped to improve this paper. We acknowledge the use of the data from SOHO, STEREO, Wind, DSCOVR, and GOES satellites and the world data center (WDC) for Geomagnetism, Kyoto. This work is supported by grants from CAS (Youth Innovation Promotion Association CAS and Key Research Program of Frontier Sciences QYZDB-SSW-DQC015), NSFC (41774181, 41774178, 41574165, 41474164, 41761134088), the Fundamental Research Funds for the Central Universities (WK2080000077), and the Specialized Research Fund for State Key Laboratories.

514.	Chen, H. Y., X. L. Gao, Quanming Lu, and S. Wang, In Situ Observations of Harmonic Alfven Waves and Associated Heavy Ion Heating, Astrophys. J., 859, 120, 2018.

513.	Liu, Lijuan, Yuming Wang, Zhenjun Zhou, Karin Dissauer, Manuela Temmer, and Jun Cui, A Comparative Study between a Failed and a Successful Eruption Initiated from the Same Polarity Inversion Line in AR 11387, Astrophys. J., 858, 121(14pp), 2018. (SDO/HMI Science Nugget http://hmi.stanford.edu/hminuggets/?p=2481)
Abstract. In this paper, we analyzed a failed and a successful eruption that initiated from the same polarity inversion line within NOAA AR 11387 on 2011 December 25. They both started from a reconnection between sheared arcades, with distinct pre-eruption conditions and eruption details: before the failed one, the magnetic fields of the core region had a weaker non-potentiality; the external fields had a similar critical height for torus instability, and a similar local torus-stable region, but a larger magnetic flux ratio (of low corona and near-surface region) compared to the successful one. During the failed eruption, a smaller Lorentz force impulse was exerted on the outward ejecta; the ejecta had a much slower rising speed. Factors that might lead to the initiation of the failed eruption are identified: (1) a weaker non-potentiality of the core region, and a smaller Lorentz force impulse gave the ejecta a small momentum; (2) the large flux ratio, and the local torus-stable region in the corona provided strong confinements that made the erupting structure regain an equilibrium state. We thank our anonymous referee for his/her valuable comments that helped to improve this paper. We acknowledge the use of the data from GOES, from HMI and AIA instruments on board SDO, and from the EUVI, COR1, and COR2 instruments on board STEREO. L.L. is supported by the grants from the Open Project of CAS Key Laboratory of Geospace Environment. Y.W. is supported by grants from NSFC (41574165 and 41774178). K.D. acknowledges the support by the Austrian Space Applications Program of the Austrian Research Promotion Agency FFG (ASAP-11 4900217). M.T. acknowledges support by the FFG/ASAP Programme under grant No. 859729 (SWAMI). J.C. is supported by NSFC through grants 41525015 and 41774186.

512.	Yang, Z. W., Quanming Lu, Y. D. Liu, and R. Wang, Impact of shock front rippling and self-reforming on the electron dynamics of low-Mach-number shock, Astrophys. J., 857, 36, 2018.

511.	Awasthi, Arun Kumar, Rui Liu, Haimin Wang, Yuming Wang, and Chenglong Shen, Pre-eruptive Magnetic Reconnection within a Multi-flux-rope System in the Solar Corona, Astrophys. J., 857, 124(13pp), 2018.
Abstract. The solar corona is frequently disrupted by coronal mass ejections (CMEs), whose core structure is believed to be a flux rope made of helical magnetic field. This has become a “standard” picture; though, it remains elusive how the flux rope forms and evolves toward eruption. While one-third of the ejecta passing through spacecraft demonstrate a flux-rope structure, the rest have complex magnetic fields. Are they originating from a coherent flux rope, too? Here we investigate the source region of a complex ejecta, focusing on a flare precursor with definitive signatures of magnetic reconnection, i.e., nonthermal electrons, flaring plasma, and bidirectional outflowing blobs. Aided by nonlinear force-free field modeling, we conclude that the reconnection occurs within a system of multiple braided flux ropes with different degrees of coherency. The observation signifies the importance of internal structure and dynamics in understanding CMEs and in predicting their impacts on Earth. A.K.A. and R.L. are supported by NSFC 41474151, 41774150, and 41761134088. A.K.A. acknowledges the International postdoctoral program of USTC. H.W. is supported by NSF AGS-1408703 and AGS-1620875. Y.W. acknowledges the support from NSFC 41774178 and 41574165. C.S. is supported by NSFC 41774181. This work is also supported by NSFC 41421063, CAS Key Research Program of Frontier Sciences QYZDB-SSW-DQC015, and the fundamental research funds for the central universities. Software: SolarSoftWare (Freeland & Handy 2012).

510.	Liu, Jiajia, Yudong Ye, Chenglong Shen, Yuming Wang, and Robert Erdelyi, A New Tool for CME Arrival Time Prediction Using Machine Learning Algorithms: CAT-PUMA, Astrophys. J., 855, 109(10pp), 2018.
Abstract. Coronal mass ejections (CMEs) are arguably the most violent eruptions in the solar system. CMEs can cause severe disturbances in interplanetary space and can even affect human activities in many aspects, causing damage to infrastructure and loss of revenue. Fast and accurate prediction of CME arrival time is vital to minimize the disruption that CMEs may cause when interacting with geospace. In this paper, we propose a new approach for partial-/full halo CME Arrival Time Prediction Using Machine learning Algorithms (CAT-PUMA). Via detailed analysis of the CME features and solar-wind parameters, we build a prediction engine taking advantage of 182 previously observed geo-effective partial-/full halo CMEs and using algorithms of the Support Vector Machine. We demonstrate that CAT-PUMA is accurate and fast. In particular, predictions made after applying CAT-PUMA to a test set unknown to the engine show a mean absolute prediction error of ∼5.9 hr within the CME arrival time, with 54% of the predictions having absolute errors less than 5.9 hr. Comparisons with other models reveal that CAT-PUMA has a more accurate prediction for 77% of the events investigated that can be carried out very quickly, i.e., within minutes of providing the necessary input parameters of a CME. A practical guide containing the CATPUMA engine and the source code of two examples are available in the Appendix, allowing the community to perform their own applications for prediction using CAT-PUMA. The SOHO LASCO CME catalog is generated and maintained at the CDAW Data Center by NASA and The Catholic University of America in cooperation with the Naval Research Laboratory. SOHO is a project of international cooperation between ESA and NASA. J.L. appreciates discussions with Dr. Xin Huang (National Astronomical Observatories, Chinese Academy of Sciences). We thank Dr. Manolis K. Georgoulis (Research Center for Astronomy and Applied Mathematics, Academy of Athens) for his useful advice in improving this paper. J.L. and R.E. acknowledge the support (grant number ST/M000826/1) received by the Science and Technology Facility Council (STFC), UK. R.E. is grateful for the support received from the Royal Society (UK). Y.W. is supported by grants 41574165 and 41774178 from NSFC.

509.	Liu, Jiajia, Robert Erdelyi, Yuming Wang, and Rui Liu, Untwisting jets related to magnetic flux cancellation, Astrophys. J., 852, 10(12pp), 2018.
Abstract. The rotational motion of solar jets is believed to be a signature of the untwisting process resulting from magnetic reconnection, which takes place between twisted closed magnetic loops (i.e., magnetic flux ropes) and open magnetic field lines. The identification of the pre-existing flux rope, and the relationship between the twist contained in the rope and the number of turns the jet experiences, are then vital in understanding the jet-triggering mechanism. In this paper, we will perform a detailed analysis of imaging, spectral, and magnetic field observations of four homologous jets, among which the fourth one releases a twist angle of 2.6π. Nonlinear force-free field extrapolation of the photospheric vector magnetic field before the jet eruption presents a magnetic configuration with a null point between twisted and open fields—a configuration highly in favor of the eruption of solar jets. The fact that the jet rotates in the opposite sense of handness to the twist contained in the pre-eruption photospheric magnetic field confirms the unwinding of the twist by the jet’s rotational motion. The temporal relationship between jets’ occurrence and the total negative flux at their source region, together with the enhanced magnetic submergence term of the photospheric Poynting flux, shows that these jets are highly associated with local magnetic flux cancellation. We thank the referee for his thorough comments and suggestions. We acknowledge the use of observations from SDO and IRIS. Vector magnetic field data is courtesy of the HMI science team. We acknowledge the use of codes in the following papers: Welsch & Longcope (2003; YAFTA), Wiegelmann (2008; NLFFF), and Schuck (2008; DAVE4VM). J.L. also benefits from discussions with Dr. Etienne Pariat. J.L. and R.E. acknowledge the support received by the Science and Technology Facility Council (STFC), UK. R.E. is grateful for the support received from the Royal Society (UK). This work is also supported by the Anhui Provincial Natural Science Foundation, China. Y.W. is supported by the grants 41574165 and 41421063 from NSFC. R.L. is supported by grants 41774150 and 41474151 from NSFC.

508.	Zhao, Ake, Yuming Wang, Hengqiang Feng, Mengjiao Xu, Yan Zhao, Guoqing Zhao, and Qiang Hu, The twist profile in the cross-section of interplanetary magnetic clouds, Astrophys. J. Lett., 869, L13(6pp), 2018.
Abstract. Magnetic flux ropes (MFRs) as a well-organized magnetic field structure embedded in space plasmas have been widely studied for several decades. The twists of magnetic field lines in MFRs can yield much information regarding the formation and stability of MFRs, yet there is still open debate about them. Here, with the aid of a uniform-twist force-free flux rope model, we study the twist profile in the cross section of a interplanetary magnetic cloud (MC) by peeling off equal azimuthal mgnetic flux layer by layer from the outermost shell, just like peeling an onion. The absolute value of the average twist, t, and the twist in each layer, τ, exhibit an almost monotonous decrease from the axis to the periphery of the MC, but τ has a larger relative error. However, they do have a coincident trend of a high-twist core and an low-twist outer shell. The twist number per unit length, t/τ, follows a linear trend versus l/Rpi, where R is the radius of each layer, with a correlation coefficient of 0.96/0.91 and slope of 0.27/0.26, which is well below the critical slope of 1 suggested by Wang et al. We acknowledge the use of data from the Wind spacecraft. This research is supported by NSFC grants 41804163, 41774178, 41761134088, 41574165, and 41674170.

507.	Liu, Lijuan, Xin Cheng, Yuming Wang, Zhenjun Zhou, Yang Guo, and Jun Cui, Rapid Buildup of a Magnetic Flux Rope during a Confined X2.2 Class Flare in NOAA AR 12673, Astrophys. J. Lett., 867, L5, 2018.
Abstract. Magnetic flux ropes (MFRs) are believed to be the core structure in solar eruptions; nevertheless, their formation remains intensely debated. Here we report a rapid buildup process of an MFR system during a confined X2.2 class flare occurred on 2017 September 6 in NOAA active region (AR) 12673, three hours after which the structure erupted to a major coronal mass ejection (CME) accompanied by an X9.3 class flare. For the X2.2 flare, we do not find extreme ultraviolet dimmings, separation of its flare ribbons, or clear CME signatures, suggesting a confined flare. For the X9.3 flare, large-scale dimmings, separation of flare ribbons, and a CME show it to be eruptive. By performing a time sequence of nonlinear force-free fields extrapolations we find the following. Until the eruptive flare, an MFR system was located in the AR. During the confined flare, the axial flux and the lower bound of the magnetic helicity for the MFR system were dramatically enhanced by about 86% and 260%, respectively, although the mean twist number was almost unchanged. During the eruptive flare, the three parameters were all significantly reduced. The results evidence the buildup and release of the MFR system during the confined and the eruptive flare, respectively. The former may be achieved by flare reconnection. We also calculate the pre-flare distributions of the decay index above the main polarity inversion line and find no significant difference. It indicates that the buildup of the magnetic flux and helicity of the MFR system may play a role in facilitating its final eruption. We thank our anonymous referee for constructive comments that significantly improved the manuscript. We thank Jie Zhang for his helpful discussions. We acknowledge the data from GOES, SDO, and SOHO. L.L. is supported by the Open Project of CAS Key Laboratory of Geospace Environment, and NSFC (11803096). X.C. is funded by NSFC (11722325, 11733003, 11790303, 11790300), Jiangsu NSF (BK20170011), and “Dengfeng B” program of Nanjing University. Y.W. is supported by NSFC (41574165, 41774178). Y.G. is supported by NSFC (11773016, 11533005) and the fundamental research funds for the central universities 020114380028. J.C. is supported by NSFC (41525015, 41774186).

506.	Wang, Haimin, Rui Liu, Qin Li, Chang Liu, Na Deng, Yan Xu, Ju Jing, Yuming Wang, and Wenda Cao, Extending Counter-Streaming Motion from an Active Region Filament to a Sunspot Light Bridge, Astrophys. J. Lett., 852, L18(6pp), 2018.
Abstract.

505.	Wu, M. Y., Quanming Lu, M. Volwerk, R. Nakamura, and T. L.Zhang, Electron acceleration behind a wavy dipolarization front, Astrophys. & Space Sci., 363, 22, 2018.

504.	Jin, Y. J., Zheng, H. N., and Su, Z. P., Propagation and Damping of two-fluid magnetohydrodynamic waves in stratified solar atmosphere, Chinese Phys. Lett.*, 35, 075201, 2018.

503.	Wang, R. S., Quanming Lu, R. Nakamura, W. Baumjohann, C. T. Russell, J. L. Burch, C. J. Pollock, D. Gershman, R. E. Ergun, S. Wang, P. A. Lindqvist, and B. Giles, An electron-scale current sheet without bursty reconnection signatures observed in the near-Earth tail, Geophys. Res. Lett., 45, 4542-4549, 2018.

502.	Xu, S. X., A. Runov, A. Artemyev, V. Angelopoulos, and Quanming Lu, Intense cross-tail field-aligned currents in the plasma sheet at lunar distances, Geophys. Res. Lett., 45, 4610-4617, 2018.

501.	Chen, L. J., J. C. Sun, Quanming Lu, X. Y. Wang, X. L. Gao, and S. Wang, Two-dimensional particle-in-cell simulation of magnetosonic wave excitation in a dipole magnetic field, Geophys. Res. Lett., 45, 8712-8720, 2018.

500.	Gao, X. L., J. C. Sun, Quanming Lu, L. J. Chen, and S. Wang, Generation of unusual lower harmonic magnetosonic waves through nonlinear wave-wave interactions, Geophys. Res. Lett., 45, 8029-8034, 2018.

499.	Su, Z. P., Liu, N. G., Zheng, H. N., Wang, Y. M., and Wang, S., Large-amplitude extremely low frequency hiss waves in plasmaspheric plumes, Geophys. Res. Lett.*, 45, 565-577, 2018.

498.	Liu, N. G., Su, Z. P., Zheng, H. N., Wang, Y. M., and Wang, S., Prompt disappearance and emergence of radiation belt magnetosonic waves induced by solar wind dynamic pressure variations, Geophys. Res. Lett.*, 45, 585-594, 2018.

497.	Liu, N. G., Su, Z. P., Zheng, H. N., Wang, Y. M., and Wang, S., Magnetosonic harmonic falling and rising frequency emissions potentially generated by nonlinear wave-wave interactions in the Van Allen radiation belts, Geophys. Res. Lett.*, 45, 2018.

496.	Su, Z. P., Liu, N. G., Zheng, H. N., Wang, Y. M., and Wang, S., Multipoint observations of nightside plasmaspheric hiss generated by substorm injected electrons, Geophys. Res. Lett.*, 45, 10921-10932, 2018.

495.	Gao, Z. L., Su, Z. P., Xiao, F. L., Summers, D., Liu, N. G., Zheng, H. N., Wang, Y. M., Wei, F. S., and Wang, S., Nonlinear coupling between whistler-mode chorus and electron cyclotron harmonic waves in the magnetosphere, Geophys. Res. Lett.*, 45, 12685-12693, 2018.

494.	Su, Zhenpeng, Nigang, Liu, Huinan Zheng, Yuming Wang, and Shui Wang, Large-amplitude extremely low frequency hiss waves in plasmaspheric plumes, Geophys. Res. Lett., 45, 565-577, 2018.

493.	Liu, Nigang, Su, Zhenpeng, Huinan Zheng, Yuming Wang, and Shui Wang, Prompt disappearance and emergence of radiation belt magnetosonic waves induced by solar wind dynamic pressure variations, Geophys. Res. Lett., 45, 585-594, 2018.

492.	Liu, Nigang, Zhenpeng Su, Huinan Zheng, Yuming Wang, and Shui Wang, Magnetosonic harmonic falling and rising frequency emissions potentially generated by nonlinear wave-wave interactions in the Van Allen radiation belts, Geophys. Res. Lett., 45, doi:10.1029/2018GL079232, 2018.

491.	Su, Zhenpeng, Nigang Liu, Huinan Zheng, Yuming Wang, and Shui Wang, Multipoint observations of nightside plasmaspheric hiss generated by substorm injected electrons, Geophys. Res. Lett., 45, doi:10.1029/2018GL079927, 2018.

490.	Gao, Zhonglei, Zhenpeng Su, Fuliang Xiao, Danny Summers, Nigang Liu, Huinan Zheng, Yuming Wang, Fengsi Wei, and Shui Wang, Nonlinear coupling between whistler-mode chorus and electron cyclotron harmonic waves in the magnetosphere, Geophys. Res. Lett., 45, 12685-12693, 2018.

489.	Shan, L. C, C. Mazelle, K. Meziane, N. Romanelli, Y. S. Ge, A. M. Du, Quanming Lu, and T. L. Zhang, The quasi-monochromatic ULF wave boundary in the Venusian foreshock: Venus Express observations, J. Geophys. Res. - Space Phys., 123, 374-384, 2018.

488.	Chen, H. Y., X. L. Gao, Quanming Lu, J. C. Sun, and S. Wang, Nonlinear evolution of counter-propagating whistler-mode waves excited by anisotropic electrons within the equatorial source region: 1-D PIC simulations, J. Geophys. Res. - Space Phys., 123, 1200-1207, 2018.

487.	Gao, X. L., Quanming Lu, and S. Wang, Statistical results of multiband chorus by using THEMIS waveform data, J. Geophys. Res. - Space Phys., 123, 5506-5515, 2018.

486.	Tang, C. L., Xie, X. J., Ni, B., Su, Z. P., Reeves, G. D., Zhang, J.-C., Baker, D. N., Spence, H. E., Funsten, H. O., Blake, J. B., Wygant, J. R., and Dai, G. Y., Rapid enhancements of the seed populations in the heart of the Earth's outer radiation belt: A multicase study, J. Geophys. Res. - Space Phys., 123*, 4895-4907, 2018.

485.	He, Y. H., Xiao, F. L., Su, Z. P., Zheng, H. N., Yang, C., Liu, S., and Zhou, Q. H., Generation of lower L-shell dayside chorus by energetic electrons from the plasmasheet, J. Geophys. Res. - Space Phys., 123, 8109-8121, 2018.

484.	Zhuang, Bin, Youqiu Hu, Yuming Wang, Quanhao Zhang, Rui Liu, Tingyu Gou, and Chenglong Shen, Coronal flux rope catastrophe associated with internal energy release, J. Geophys. Res. - Space Phys., 123, 2513-2519, 2018.
Abstract. Magnetic energy during the catastrophe was predominantly studied by the previous catastrophe works since it is believed to be the main energy supplier for the solar eruptions. However, the contribution of other types of energies during the catastrophe cannot be neglected. This paper studies the catastrophe of the coronal flux rope system in the solar wind background, with emphasis on the transformation of different types of energies during the catastrophe. The coronal flux rope is characterized by its axial and poloidal magnetic fluxes and total mass. It is shown that a catastrophe can be triggered by not only an increase but also a decrease of the axial magnetic flux. Moreover, the internal energy of the rope is found to be released during the catastrophe so as to provide energy for the upward eruption of the flux rope. As far as the magnetic energy is concerned, it provides only part of the energy release, or even increases during the catastrophe, so the internal energy may act as the dominant or even the unique energy supplier during the catastrophe. This work was supported by the grants from NSFC (41774178, 41574165, 41421063, and 41274173), and the fundamental research funds for the central universities. The data and code scripts used in this paper can be found online at https://doi.org/10.6084/m9.figshare.5955616.

483.	Wang, Yuming, Chenglong Shen, Rui Liu, Jiajia Liu, Jingnan Guo, Xiaolei Li, Mengjiao Xu, Qiang Hu, and Tielong Zhang, Understanding the twist distribution inside magnetic flux ropes by anatomizing an interplanetary magnetic cloud, J. Geophys. Res. - Space Phys., 123, 3238-3261, doi:10.1002/2017JA024971, 2018. (Editor's Highlight: https://eos.org/editor-highlights/anatomy-of-a-flux-rope-hurtling-through-the-solar-system)
Abstract. Magnetic flux rope (MFR) is the core structure of the greatest eruptions, that is, the coronal mass ejections (CMEs), on the Sun, and magnetic clouds are posteruption MFRs in interplanetary space. There is a strong debate about whether or not a MFR exists prior to a CME and how the MFR forms/grows through magnetic reconnection during the eruption. Here we report a rare event, in which a magnetic cloud was observed sequentially by four spacecraft near Mercury, Venus, Earth, and Mars, respectively. With the aids of a uniform-twist flux rope model and a newly developed method that can recover a shock-compressed structure, we find that the axial magnetic flux and helicity of the magnetic cloud decreased when it propagated outward but the twist increased. Our analysis suggests that the “pancaking” effect and “erosion” effect may jointly cause such variations. The significance of the pancaking effect is difficult to be estimated, but the signature of the erosion can be found as the imbalance of the azimuthal flux of the cloud. The latter implies that the magnetic cloud was eroded significantly leaving its inner core exposed to the solar wind at far distance. The increase of the twist together with the presence of the erosion effect suggests that the posteruption MFR may have a high-twist core enveloped by a less-twisted outer shell. These results pose a great challenge to the current understanding on the solar eruptions as well as the formation and instability of MFRs. We acknowledge the use of the data from the magnetometers on board the MESSENGER, VEX, andWind spacecraft, the Solar Wind Experiment (SWE) on boardWind spacecraft, the RAD on board the MSL, and EUV imagers and coronagraphs on board the Solar Dynamics Observatory (SDO), Solar and Heliospheric Observatory (SOHO), and the twin Solar Terrestrial Relations Observatories (STEREO).We do appreciate the constructive comments from anonymous referees. which make the paper much better. Y. W. is grateful to the valuable discussion with Hui Li from Los Alamos National Laboratory about the astrophysical jets and high-twist phenomena. J. G. acknowledges stimulating discussions with the ISSI team “Radiation Interactions at Planetary Bodies” and thanks ISSI for its hospitality. Y. W. acknowledges the support from NSFC grants 41774178 and 41574165, R. L. the support from NSFC grants 41474151 and 41774150 and the Thousand Young Talents Program of China, J. L. the support from the Science and Technology Facility Council (STFC) of UK, and Q. H. partial support from NASA grant NNX14AF41G and NRL contract N00173-14-1-G006. This work is also supported by NSFC grants 41761134088 and 41421063 and the fundamental research funds for the central universities.

482.	Li, Xiaolei, Yuming Wang, Rui Liu, Chenglong Shen, Quanhao Zhang, Bin Zhuang, Jiajia Liu, and Yutian Chi, Reconstructing solar wind inhomogeneous structures from stereoscopic observations in white-light: Small transients along the Sun-Earth line, J. Geophys. Res. - Space Phys., 123*, 7257-7270, doi:10.1029/2018JA025485, 2018.
Abstract. The Heliospheric Imagers (HI) onboard the two spacecraft of the Solar Terrestrial Relations Observatory (STEREO) provided white-light images of transients in the solar wind from dual perspectives from 2007 to 2014. In this paper, we develop a new method to identify and locate the transients automatically from simultaneous images from the two inner telescopes, known as HI-1, based on a correlation analysis. Correlation coefficient (cc) maps along the Sun-Earth line are constructed for the period from 1 January 2010 to 28 February 2011. From the maps, transients propagating along the Sun-Earth line are identified, and a 27-day periodic pattern is revealed, especially for small-scale transients. Such a periodicity in the transient pattern is consistent with the rotation of the Sun’s global magnetic structure and the periodic crossing of the streamer structures and slow solar wind across the Sun-Earth line, and this substantiates the reliability of our method and the high degree of association between the small-scale transients of the slow solar wind and the coronal streamers. Besides, it is suggested by the cc map that small-scale transients along the Sun-Earth line are more frequent than large-scale transients by a factor of at least 2, and that they quickly diffused into background solar wind within about 40 Rs in terms of the signal-to-noise ratio of white-light emissions. The method provides a new tool to reconstruct inhomogeneous structures in the heliosphere from multiple perspectives. The STEREO/SECCHI data are produced by a consortium of NRL (USA), RAL (UK), LMSAL (USA), GSFC (USA), MPS (Germany), CSL (Belgium), IOTA (France), and IAS (France). The SECCHI data presented in this paper were obtained from STEREO Science Center (https://stereo-ssc.nascom.nasa.gov/data/ins_data/secchi_hi/L2/). The Wind data were obtained from the Space Physics Data Facility (https://cdaweb.sci.gsfc.nasa.gov/). This work is supported by the grants from NSFC (41574165, 41774178, and 41761134088) and the Fundamental Research Funds for the Central Universities (WK2080000077).

481.	Liemohn, Michael W., Yuming Wang, Alan Rodger, Michael Balikhin, and Larry Kepko, Editorial: Thank you to the 2017 JGR Space Physics reviewers, J. Geophys. Res. - Space Phys., 123, 4510-4516, 2018.

480.	Hui Zhu, Yuri Y. Shprits, Lunjin Chen, Xu Liu, and Adam C. Kellerman, An Event on Simultaneous Amplification of Exohiss and Chorus Waves Associated With Electron Density Enhancements, J. Geophys. Res. - Space Phys., , 2018.

479.	Huang, K., Quanming Lu, L. Gao, H. T. Ji, X. Y. Wang, and F. B. Fan, Particle-in-cell simulations of magnetically driven reconnection using laser-powered capacitor coils, Phys. Plasmas, 25, 052104, 2018.

478.	Sang, L. L., Quanming Lu, R. S. Wang, K. Huang, and S. Wang, Quadrupolar and hexapolar Hall magnetic field during asymmetric magnetic reconnection without a guide field, Phys. Plasmas, 25, 062120, 2018.

477.	Ke, Y. G., X. L. Gao, Quanming Lu, Y. F. Hao, and S. Wang, Parametric Decay of Nonparallel Whistler Waves in the Earth's Magnetosphere: 2-D PIC Simulations, Phys. Plasmas, 25, 072901, 2018.

476.	Quanming Lu, H. Y. Wang, K. Huang, R. S. Wang, and S. Wang, Formation of power law spectra of energetic electrons during multiple X line magnetic reconnection with a guide field, Phys. Plasmas, 25, 072126, 2018.

475.	Chi, Yutian, Chenglong Shen, Bingxian Luo, Yuming Wang, and Mengjiao Xu, Geoeffectiveness of Stream Interaction Regions from 1995 to 2016, Space Weather*, 16, 1960-1971, 2018.

474.	Guo, Jingnan, Mateja Dumbovic, Robert F. Wimmer-Schweingruber, Manuela Temmer, Henning Lohf, Yuming Wang, Astrid Veronig, Donald M. Hassler, Leila M. Mays, Cary Zeitlin, Bent Ehresmann, Oliver Witasse, Johan L. Freiherr von Forstner, Bernd Heber, and Mats Holmstrom, Modeling the evolution and propagation of 10 September 2017 CMEs and SEPs arriving at Mars constrained by remote sensing and in situ measurement, Space Weather, 16, 1156-1169, 2018. (Highlighted by http://svs.gsfc.nasa.gov/4699,)
Abstract. On 10 September 2017, solar energetic particles originating from the active region 12673 produced a ground level enhancement at Earth. The ground level enhancement on the surface of Mars, 160 longitudinally east of Earth, observed by the Radiation Assessment Detector (RAD) was the largest since the landing of the Curiosity rover in August 2012. Based on multipoint coronagraph images and the Graduated Cylindrical Shell model, we identify the initial 3-D kinematics of an extremely fast coronal mass ejection (CME) and its shock front, as well as another two CMEs launched hours earlier with moderate speeds. The three CMEs interacted as they propagated outward into the heliosphere and merged into a complex interplanetary CME (ICME). The arrival of the shock and ICME at Mars caused a very significant Forbush decrease seen by RAD only a few hours later than that at Earth, which was about 0.5 AU closer to the Sun. We investigate the propagation of the three CMEs and the merged ICME together with the shock, using the drag-based model and the WSA-ENLIL plus cone model constrained by the in situ observations. The synergistic study of the ICME and solar energetic particle arrivals at Earth and Mars suggests that to better predict potentially hazardous space weather impacts at Earth and other heliospheric locations for human exploration missions, it is essential to analyze (1) the eruption of the flare and CME at the Sun, (2) the CME kinematics, especially during their interactions, and (3) the spatially and temporally varying heliospheric conditions, such as the evolution and propagation of the stream interaction regions. We acknowledge use of NASA/SPDF OMNIWeb service and OMNI data, EU NMDB database (www.nmdb.eu), STEREO data (https://stereo-ssc.nascom.nasa.gov/), and NOAA GOES data (https://satdat.ngdc.noaa.gov/). ENLIL with Cone Model was developed by D. Odstrcil at George Mason University. MSL RAD is supported by NASA (HEOMD) under JPL subcontract 1273039 to SWRI, and in Germany by DLR (under German Space Agency grants 50QM0501, 50QM1201, and 50QM1701) to the Christian-Albrechts-University of Kiel. RAD data are archived in the NASA planetary data systems’ planetary plasma interactions node (http://ppi.pds.nasa.gov/). The Swedish contribution to the ASPERA-3 experiment is supported by the Swedish National Space Board. ASPERA-3 data are public at the ESA Planetary Science Archive. M. D. acknowledges funding from the EU H2020 MSCA grant agreement (745782). M. T. acknowledges the support by the FFG/ASAP program under grant 859729 (SWAMI). Y. W. is supported by the grants from NSFC (41574165 and 41774178). A. M. V. acknowledges support from the Austrian Science Fund (FWF): P27292-N20. J. G. thanks Christina Lee, Andreas Klassen, Fernando Carcaboso, Nina Dresing, and Andreas Taut for helpful advices and discussions. J. G. and R. F.W. S. acknowledge discussions during various ISSI team meetings.

473.	Chi, Yutian, Chenglong Shen, Bingxian Luo, Yuming Wang, and Mengjiao Xu, Geoeffectiveness of Stream Interaction Regions from 1995 to 2016, Space Weather, 16, 1960-1971, 2018.
Abstract.

472.	Wang, Jingjing, Xianzhi Ao, Yuming Wang, Chuanbing Wang, Yanxia Cai, Bingxian Luo, Siqing Liu, Chenglong Shen, Bin Zhuang, Xianghui Xue, and Jiancun Gong, An operational solar wind prediction system transitioning fundamental science to operations, J. Space Weather Space Clim., 8, A39, 2018.
Abstract. We present in this paper an operational solar wind prediction system. The system is an outcome of the collaborative efforts between scientists in research communities and forecasters at Space Environment Prediction Center (SEPC) in China. This system is mainly composed of three modules: (1) a photospheric magnetic field extrapolation module, along with the Wang-Sheeley-Arge (WSA) empirical method, to obtain the background solar wind speed and the magnetic field strength on the source surface; (2) a modified Hakamada-Akasofu-Fry (HAF) kinematic module for simulating the propagation of solar wind structures in the interplanetary space; and (3) a coronal mass ejection (CME) detection module, which derives CME parameters using the ice-cream cone model based on coronagraph images. By bridging the gap between fundamental science and operational requirements, our system is finally capable of predicting solar wind conditions near Earth, especially the arrival times of the co-rotating interaction regions (CIRs) and CMEs. Our test against historical solar wind data from 2007 to 2016 shows that the hit rate (HR) of the high-speed enhancements (HSEs) is 0.60 and the false alarm rate (FAR) is 0.30. The mean error (ME) and the mean absolute error (MAE) of the maximum speed for the same period are 73.9 km s-1 and 101.2 km s-1, respectively. Meanwhile, the ME and MAE of the arrival time of the maximum speed are 0.15 days and 1.27 days, respectively. There are 25 CMEs simulated and the MAE of the arrival time is 18.0 h. We thank the SOHO LASCO instrument team for providing the coronal observations. We also thank the ACE MAG and SWEPAM instrument team and ACE science data center for providing their data. This work is supported by the National Natural Science Foundation of China (Grant No. 41604149, 41474164, 41574165, 41761134088, 41574167, 41774181), and by the Youth Innovation Promotion Association CAS. The editor thanks two anonymous referees for their assistance in evaluating this paper.

471.	章伟杭, 郝新军, 李毅人, 王淑文, 封常青, 陈满明, 杨小平, 胡任翔, 单旭, and 汪毓明, 半空间低能离子谱仪高压电源设计, 核电子学与探测技术*, , 459-463, 2018.

2017 Top

470.	Wang, Yuming and Rui Liu, Existing an Upper Limit in the Magnetic Energy of a Stable Magnetic Flux Rope?, Res. Notes AAS, 1, 10, 2017.

469.	Lin, M. N., M. Liu, G. H. Zhu, P. Y. Shi, J. Zheng, Quanming Lu, and Xuan Sun, Field-reversed configuration formed by in-vessel θ−pinch in a tandem mirror device, Review of Scientific Instruments, 88, 093505, 2017.

468.	Liu, N. G., Zheng, H. N., and Su, Z. P., Three-dimensional ray-tracing simulation of fast magnetoacoustic waves in a stratified solar atmosphere, Sci. China Tech. Sci.*, 60, 1570-1576, 2017.

467.	Wang, Y. Y, F. Y. Li, M. Chen, S. M. Weng, Quanming Lu, Q. L. Dong, Z. M. Sheng, and J. Zhang, Magnetic field annihilation and reconnection driven by femtosecond lasers in inhomogeneous plasma, Science China, 60, 115211, 2017.

466.	Zhuang, Bin, Yuming Wang, Chenglong Shen, Siqing Liu, Jingjing Wang, Zonghao Pan, Huimin Li, and Rui Liu, The significance of the influence of the CME deflection in interplanetary space on the CME arrival at the Earth, Astrophys. J., 845*, 117(12pp), 2017.
Abstract. As one of the most violent astrophysical phenomena, coronal mass ejections (CMEs) have strong potential space weather effects. However, not all Earth-directed CMEs encounter the Earth and produce geo-effects. One reason is the deflected propagation of CMEs in interplanetary space. Although there have been several case studies clearly showing such deflections, it has not yet been statistically assessed how significantly the deflected propagation would influence the CME’s arrival at Earth. We develop an integrated CME-arrival forecasting (iCAF) system, assembling the modules of CME detection, three-dimensional (3D) parameter derivation, and trajectory reconstruction to predict whether or not a CME arrives at Earth, and we assess the deflection influence on the CME-arrival forecasting. The performance of iCAF is tested by comparing the two-dimensional (2D) parameters with those in the Coordinated Data Analysis Workshop (CDAW) Data Center catalog, comparing the 3D parameters with those of the gradual cylindrical shell model, and estimating the success rate of the CME Eartharrival predictions. It is found that the 2D parameters provided by iCAF and the CDAW catalog are consistent with each other, and the 3D parameters derived by the ice cream cone model based on single-view observations are acceptable. The success rate of the CME-arrival predictions by iCAF with deflection considered is about 82%, which is 19% higher than that without deflection, indicating the importance of the CME deflection for providing a reliable forecasting. Furthermore, iCAF is a worthwhile project since it is a completely automatic system with deflection taken into account. We acknowledge the use of the data from the SOHO spacecraft and the use of the CME catalog. SOHO is a mission of international cooperation between ESA and NASA. The CME catalog is generated and maintained at the CDAW Data Center by NASA and The Catholic University of America in cooperation with the Naval Research Laboratory. We also acknowledge the test of iCAF that took place at the Space Environment Prediction Center of the National Space Science Center, Chinese Academy of Sciences. This work is supported by grants from NSFC (41574165, 41421063, 41274173, and 41474151), and fundamental research funds for the central universities.

465.	Zhao, Ake, Yuming Wang, Jiajia Liu, Zhenjun Zhou, Chenglong Shen, Rui Liu, Bin Zhuang, and Quanhao Zhang, The role of viscosity in causing the plasma poloidal motion in magnetic clouds, Astrophys. J., 845*, 109(6pp), 2017.
Abstract.

464.	Liu, Lijuan, Yuming Wang, Rui Liu, Zhenjun Zhou, M. Temmer, J. K. Thalmann, Jiajia Liu, Kai Liu, Chenglong Shen, Quanhao Zhang, and A. M. Veronig, The causes of quasi-homologous CMEs, Astrophys. J., 844, 141(19pp), 2017.
Abstract. In this paper, we identified the magnetic source locations of 142 quasi-homologous (QH) coronal mass ejections (CMEs), of which 121 are from solar cycle (SC) 23 and 21 from SC 24. Among those CMEs, 63% originated from the same source location as their predecessor (defined as S-type), while 37% originated from a different location within the same active region as their predecessor (defined as D-type). Their distinctly different waiting time distributions, peaking around 7.5 and 1.5hr for S- and D-type CMEs, suggest that they might involve different physical mechanisms with different characteristic timescales. Through detailed analysis based on nonlinear forcefree coronal magnetic field modeling of two exemplary cases, we propose that the S-type QH CMES might involve a recurring energy release process from the same source location (by magnetic free energy replenishment), whereas the D-type QH CMEs can happen when a flux tube system is disturbed by a nearby CME. We thank our anonymous referee for his/her constructive comments that significantly improved the manuscript. We acknowledge the use of the data from HMI and AIA instruments on board Solar Dynamics Observatory (SDO); EIT, MDI, and LASCO instruments on board Solar and Heliospheric Observatory (SOHO); and Transition Region and Coronal Explorer (TRACE). This work is supported by the grants from NSFC (41574165, 41421063, 41274173, 41474151, 41131065), CAS (Key Research Program KZZDEW-01-4), MOEC (20113402110001), and the fundamental research funds for the central universities.

463.	Huang, C, Quanming Lu, R. S. Wang, F. Guo, M. Y. Wu, S. Lu, and S. Wang, Development of turbulent magnetic reconnection in magnetic island, Astrophys. J., 835, 245, 2017.

462.	Zhang, Quanhao, Yuming Wang, Youqiu Hu, Rui Liu, and Jiajia Liu, Influence of Photospheric Magnetic Conditions on the Catastrophic Behaviors of Flux Ropes in Active Regions, Astrophys. J., 835, 211(10pp), 2017.
Abstract. Since only the magnetic conditions at the photosphere can be routinely observed in current observations, it is of great significance to determine the influences of photospheric magnetic conditions on solar eruptive activities. Previous studies about catastrophe indicated that the magnetic system consisting of a flux rope in a partially open bipolar field is subject to catastrophe, but not if the bipolar field is completely closed under the same specified photospheric conditions. In order to investigate the influence of the photospheric magnetic conditions on the catastrophic behavior of this system, we expand upon the 2.5-dimensional ideal magnetohydrodynamic model in Cartesian coordinates to simulate the evolution of the equilibrium states of the system under different photospheric flux distributions. Our simulation results reveal that a catastrophe occurs only when the photospheric flux is not concentrated too much toward the polarity inversion line and the source regions of the bipolar field are not too weak; otherwise no catastrophe occurs. As a result, under certain photospheric conditions, a catastrophe could take place in a completely closed configuration, whereas it ceases to exist in a partially open configuration. This indicates that whether the background field is completely closed or partially open is not the only necessary condition for the existence of catastrophe, and that the photospheric conditions also play a crucial role in the catastrophic behavior of the flux rope system. This research is supported by Grants from NSFC 41131065, 41574165, 41421063, 41474151, and 41222031, MOEC 20113402110001, CAS Key Research Program KZZD-EW-01-4, and the fundamental research funds for the central universities WK2080000077. R.L. acknowledges the support from the Thousand Young Talents Program of China.

461.	Wang, Wensi, Rui Liu, and Yuming Wang, Tornado-Like Evolution of A Kink-Unstable Solar Prominence, Astrophys. J., 834*, 38(11pp), 2017.
Abstract. We report on the tornado-like evolution of a quiescent prominence on 2014 November 1. The eastern section of the prominence first rose slowly, transforming into an arch-shaped structure as high as ∼150 Mm above the limb; the arch then writhed moderately in a left-handed sense, while the original dark prominence material emitted in the Fe IX 171 Å passband, and a braided structure appeared at the eastern edge of the warped arch. The unraveling of the braided structure was associated with a transient brightening in the EUV and apparently contributed to the formation of a curtain-like structure (CLS). The CLS consisted of myriad thread-like loops rotating counterclockwise about the vertical if viewed from above. Heated prominence material was observed to slide along these loops and land outside the filament channel. The tornado eventually disintegrated and the remaining material flew along a left-handed helical path constituting approximately a full turn, as corroborated through stereoscopic reconstruction, into the cavity of the stable, western section of the prominence. We suggest that the tornado-like evolution of the prominence was governed by the helical kink instability, and that the CLS formed through magnetic reconnections between the prominence field and the overlying coronal field. We thank B.Kliem for helpful comments, and the anonymous referee for constructive suggestions. R.L. acknowledges the support from the Thousand Young Talents Program of China and NSFC 41474151. Y.W. acknowledges the support from NSFC 41131065 and 41574165. This work was also supported by NSFC 41421063, CAS Key Research Program KZZD-EW-01-4, and the fundamental research funds for the central universities.

460.	Wang, Dong, Rui Liu, Yuming Wang, Kai Liu, Jun Chen, Jiajia Liu, Zhenjun Zhou, and Min Zhang, Critical Height of the Torus Instability in Two-Ribbon Solar Flares, Astrophys. J. Lett., 843, L9(6pp), 2017. (SDO/HMI Science Nugget http://hmi.stanford.edu/hminuggets/?p=1956)
Abstract.

459.	Mishra, Wageesh, Yuming Wang, Nandita Srivastava, and Chenglong Shen, Assessing the Nature of Collisions of Coronal Mass Ejections in the Inner Heliosphere, Astrophys. J. Supp., 232, 5(24pp), 2017.
Abstract. There have been several attempts in the past to understand the nature of the collision of individual cases of interacting coronal mass ejections (CMEs). We selected eight cases of interacting CMEs and estimated their propagation and expansion speeds, and direction of impact and masses, by exploiting coronagraphic and heliospheric imaging observations. Using these estimates while ignoring the errors therein, we find that the nature of collisions is perfectly inelastic for two cases (i.e., 2012 March and November), inelastic for two cases (i.e., 2012 June and 2011 August), elastic for one case (i.e., 2013 October), and super-elastic for three cases (i.e., 2011 February, 2010 May, and 2012 September). Including the large uncertainties in the estimated directions, angular widths, and pre-collision speeds, the probability of a perfectly inelastic collision for the 2012 March and November cases drops from 98% to 60% and 100% to 40%, respectively, increasing the probability for other types of collision. Similarly, the probability of an inelastic collision drops from 95% to 50% for the 2012 June case, 85% to 50% for the 2011 August case, and 75% to 15% for the 2013 October case. We note that the probability of a superelastic collision for the 2011 February, 2010 May, and 2012 September CMEs drops from 90% to 75%, 60% to 45%, and 90% to 50%, respectively. Although the sample size is small, we find good dependence of the nature of collision on the CME parameters. The crucial pre-collision parameters of the CMEs responsible for increasing the probability of a super-elastic collision are, in descending order of priority, their lower approaching speed, expansion speed of the following CME higher than the preceding one, and a longer duration of the collision phase. We acknowledge the UK Solar System Data Center for providing the processed Level-2 STEREO/HI data. This work is supported by NSFC grant Nos. 41131065, 41574165, and 41421063. W.M. is supported by the Chinese Academy of Sciences (CAS) President’s International Fellowship Initiative (PIFI) grant No. 2015PE015. We thank the referee for insightful comments. W.M. also thanks A. K. Awasthi and A. Raghav for helpful discussions.

458.	Qiu, Q, H. G. Yang, Quanming Lu, and Z. J. Hu, Correlation between emission intensities in dayside auroral arcs and precipitating electron spectra, Chinese J. Geophys., 60, 489-498, 2017.

457.	Sang, L. L., M. Y. Wu, and Quanming Lu, Electrostatic Structure of the electron phase-space holes generated by the electron two-stream instabilities with a finite width, Chinese J. Space Sci., 37, 517-523, 2017.

456.	Gao, X. L., Y. G. Ke, Quanming Lu, L. J. Chen, and S. Wang, Generation of multiband chorus in the earth’s magnetosphere: 1-D PIC simulation, Geophys. Res. Lett., 44, 618-624, 2017.

455.	Gao, X. L., Quanming Lu, and S. Wang, First Report of Resonant Interactions Between Whistler-mode Waves in the Earth's Magnetosphere, Geophys. Res. Lett., 44, 5269-5275, 2017.

454.	Tao, X, L. Chen, X. Liu, Quanming Lu, and S. Wang, Quasilinear analysis of saturation properties of broadband whistler mode waves, Geophys. Res. Lett., 44, 8122-8129, 2017.

453.	Gao, Z. L., Su, Z. P., Chen, L. J., Zheng, H. N., Wang, Y. M., and Wang, S., Van Allen Probes observations of whistler-mode chorus with long-lived oscillating tones, Geophys. Res. Lett.*, 44, 5909-5919, 2017.

452.	Liu, N. G., Su, Z. P., Gao, Z. L., Zheng, H. N., Wang, Y. M., Wang, S., Spence, H. E. Reeves, G. D., Baker, D. N., Blake, J. B., Funsten, H. O., and Wygant, J. R., Simultaneous disappearances of plasmaspheric hiss, exohiss and chorus waves triggered by a sudden decrease in solar wind dynamic pressure, Geophys. Res. Lett.*, 44, 52-61, 2017.

451.	Yang, C., Su, Z. P., Xiao, F. L., Zheng, H. N., Wang, Y. M., Wang, S., Spence, H. E. Reeves, G. D., Baker, D. N., Blake, J. B., and Funsten, H. O., A positive correlation between energetic electron butterfly distributions and magnetosonic waves in the radiation belt slot region, Geophys. Res. Lett.*, 44, 3980-3990, 2017.

450.	Su, Z. P., Wang, G., Liu, N. G., Zheng, H. N., Wang, Y. M., and Wang, S., Direct observation of generation and propagation of magnetosonic waves following substorm injection, Geophys. Res. Lett.*, 44, 7587-7597, 2017.

449.	Yang, Chang, Zhenpeng Su, Fuliang Xiao, Huinan Zheng, YumingWang, Shui Wang, H. E. Spence, G. D. Reeves, D. N. Baker, J. B. Blake, G. D. Reeves, and H. O. Funsten, A positive correlation between energetic electron butterfly distributions and magnetosonic waves in the radiation belt slot region, Geophys. Res. Lett., 44, 3980-3990, 2017.

448.	Gao, Zhonglei, Zhenpeng Su, Lunjin Chen, Huinan Zheng, Yuming Wang, and Shui Wang, Van Allen Probes observations of whistler-mode chorus with long-lived oscillating tones, Geophys. Res. Lett., 44, 5909-5919, 2017.

447.	Su, Zhenpeng, Geng Wang, Nigang Liu, Huinan Zheng, Yuming Wang, and Shui Wang, Direct observation of generation and propagation of magnetosonic waves following substorm injection, Geophys. Res. Lett., 44, 7587-7597, 2017.

446.	Sun, J. C., X. L. Gao, Quanming Lu, L. J. Chen, X. Y. Wang, X. Tao, and S. Wang, Spectral properties and associated plasma energization by magnetosonic waves in the earth's magnetosphere: particle-in-cell simulations, J. Geophys. Res. - Space Phys., 122, 5377-5390, 2017.

445.	Hao, Y. F., X. L. Gao, Quanming Lu, C. Huang, R. S. Wang, and S. Wang, Reformation of rippled quasi-parallel shocks: 2-D hybrid simulations, J. Geophys. Res. - Space Phys., 122, 6385-6396, 2017.

444.	Ke, Y. G, X. L. Gao, Quanming Lu, X. Y. Wang, and S. Wang, Generation of rising-tone chorus in a two-dimensional mirror field by using the general curvilinear PIC code, J. Geophys. Res. - Space Phys., 122, 8154-8165, 2017.

443.	Wang, C, Q. Ma, X. Tao, Y. Zhang, S. Teng, J. M. Albert, A. A. Chan, W. Li, B. Ni, Quanming Lu, and S. Wang, Modeling radiation belt dynamics using a 3-D layer method code, J. Geophys. Res. - Space Phys., 122, 8642-8658, 2017.

442.	Wang, G., Su, Z. P., Zheng, H. N., Wang, Y. M., Zhang, M., and Wang, S., Nonlinear fundamental and harmonic cyclotron resonant scattering of relativistic electrons by oblique EMIC waves, J. Geophys. Res. - Space Phys., 122*, 1928-1945, 2017.

441.	Tang, C. L., Wang, Y. X., Ni, B. B., Zhang, J. C., Reeves, G. D., Su, Z. P., Baker, D. N., Spence, H. E., Funsten, H. O., and Blake, J. B., Radiation belt seed population and its association with the relativistic electron dynamics: A statistical study, J. Geophys. Res. - Space Phys., 122*, 5261-5276, 2017.

440.	Shen, Chenglong, Yutian Chi, Yuming Wang, Mengjiao Xu, and Shui Wang, Statistical Comparison of the ICME's Geoeffectiveness of Different Types and Different Solar Phases from 1995 to 2014, J. Geophys. Res. - Space Phys., 122, 5931-5948, 2017.
Abstract. The geoeffectiveness of interplanetary coronal mass ejections (ICMEs) is an important issue in space weather research and forecasting. Based on the ICME catalog that we recently established and the Dst indices from the World Data Center, we study and compare the geoeffectiveness of ICMEs of different in situ signatures and different solar phases from 1995 to 2014. According to different in situ signatures, all ICMEs are divided into three types: isolated ICMEs (I-ICMEs), multiple ICMEs (M-ICMEs), and shock-embedded ICMEs (S-ICMEs), resulting in a total of 363 group events. The main findings of this work are as follows: (1) Fifty-eight percent of ICMEs caused geomagnetic storms with Dst min ≤ −30 nT. Further, large fraction (87%) of intense geomagnetic storms are caused by ICME groups and their sheath regions. (2) Numbers of ICME groups and the probabilities of ICME groups in causing geomagnetic storms varied in pace with the solar cycle. Meanwhile, the ICME groups and the probabilities of them in causing geomagnetic storms in Solar Cycle 24 are much lower than those in Solar Cycle 23. (3) The maximum value of the intensity of the magnetic field ( B ), south component of the magnetic field ( B s ), and dawn-dusk electric field vB s are well correlated with the intensity of the magnetic storms. (4) Shock-embedded ICMEs have a high probability in causing geomagnetic storms, especially intense geomagnetic storms. (5) The compression of shock on the south component of magnetic field is an important factor to enhance the geoeffectiveness of S-ICMEs structures. We acknowledge the use of the data from Wind and ACE satellites and the world data center (WDC). for Geomagnetism, Kyoto. The Wind/MFI, Wind/SWE, Wind/SFPD, and Wind/3DP data are downloaded from the NASA’s Space Physics Data Facility (SPDF, http://spdf.gsfc.nasa.gov/). The suprathermal electron pitch angle distribution data from ACE are gotten from http://www.srl.caltech.edu/ ACE/ASC/DATA/level3/swepam/data/. The Dst indices came from the link of http://wdc.kugi.kyoto-u.ac.jp/. The yearly sunspot number data locate at Royal Observatory of Belgium via the link http://www.sidc.be/silso/datafiles. This work is supported by grants from MOST 973 Key Project (2011CB811403), CAS (Key Research Program KZZD-EW-01, 100-Talent Program, Youth Innovation Promotion Association CAS and Key Research Program of Frontier Sciences QYZDB-SSW-DQC015), NSFC (41131065, 41121003, 41274173, 41222031, and 41404134), the Fundamental Research Funds for the Central Universities and the Specialized Research Fund for State Key Laboratories.

439.	Wang, Geng, Zhenpeng Su, Huinan Zheng, Yuming Wang, Min Zhang, and Shui Wang, Nonlinear fundamental and harmonic cyclotron resonant scattering of radiation belt ultra-relativistic electrons by oblique monochromatic EMIC waves, J. Geophys. Res. - Space Phys., 122, 1928-1945, 2017.

438.	Su Zhenpeng, H. E. Spence, Zhonglei Gao, G. D. Reeves, Huinan Zheng, D. N. Baker, Yuming Wang, Shui Wang, and J. R. Wygant, Rapid Loss of Radiation Belt Relativistic Electrons by EMIC Waves, J. Geophys. Res. - Space Phys., 122, 2017.

437.	Liu, Nigang, Zhenpeng Su, Zhonglei Gao, G. D. Reeves, Huinan Zheng, Yuming Wang, and Shui Wang, Shock-Induced Disappearance and Subsequent Recovery of Plasmaspheric Hiss: Coordinated Observations of RBSP, THEMIS, and POES Satellites, J. Geophys. Res. - Space Phys., 122, 2017.

436.	Huang, K., C. Huang, Q. L. Dong, Quanming Lu, S. Lu, Z. M. Sheng, S. Wang, and J. Zhang, Formation of high-speed electron jets as the evidence for magnetic reconnection in laser-produced plasma, Phys. Plasmas, 24, 041406, 2017.

435.	Ke, Y. G., X. L. Gao, Quanming Lu, and S. Wang, Parametric decay of a parallel propagating monochromatic whistler wave: particle-in-cell simulations, Phys. Plasmas, 24, 012108, 2017.

434.	Abid, A. A., M. Z. Khan, Quanming Lu, and S. L. Yap, A generalized AZ- non-Maxwellian velocity distribution function for space plasmas, Phys. Plasmas, 24, 033702, 2017.

433.	Wang, H. Y., Quanming Lu, C. Huang, and S. Wang, Electron acceleration in a secondary magnetic island formed during magnetic reconnection with a guide field, Phys. Plasmas, 24, 052113, 2017.

432.	Abid, A. A., M. U. Rehman, M. Z. Khan, Z. Sarfraz, and Quanming Lu, The Influence of Multi-Ions Streaming on the Variation of Dust Particles Surface Potential with Maxwellian/Non-Maxwellian Dusty Plasmas, Phys. Plasmas, 24, 083702, 2017.

431.	Huang, K., Quanming Lu, C. Huang, Q. L. Dong, H. Y. Wang, F. B. Fan, Z. M. Sheng, S. Wang, and J. Zhang, Formation of electron energy spectra during magnetic reconnection in laser-produced plasma, Phys. Plasmas, 24, 102101, 2017.

430.	Wang, R. S, R. Nakamura, Quanming Lu, W. Baumjohann, R. E. Ergun, J. L. Burch, M. Volwerk, A. Varsani, T. Nakamura, W. Gonzalez, B. Giles, D. Gershman, and S. Wang, Simultaneously observed ion- and electron-scale quadrants of the reconnection Hall magnetic field at magnetopause, Phys. Rev. Lett., 118, 175101, 2017.

429.	Zhao, Ake, Yuming Wang, Yutian Chi, Jiajia Liu, Chenglong Shen, and Rui Liu, Main cause of the poloidal plasma motion inside a magnetic cloud inferred from multiple-spacecraft observations, Sol. Phys., 292, 58, doi:10.1007/s11207-017-1077-4, 2017.
Abstract.

428.	Shen, Fang, Yuming Wang, Chenglong Shen, and Xueshang Feng, On the Collision Nature of Two Coronal Mass Ejections: A Review, Sol. Phys., 292, 104(20pp), 2017.
Abstract.

427.	Lugaz, Noe, Manuela Temmer, Yuming Wang, and Charlie Farrugia, The Interaction of Successive Coronal Mass Ejections: A Review, Sol. Phys., 292, 64(37pp), 2017.
Abstract.

2016 Top

426.	Lu, S., Quanming Lu, F. Guo, Z. M. Sheng, H. Y. Wang, and S. Wang, Particle-in-cell simulations of electron energization in laser-driven magnetic reconnection, New Journal of Physics, 18, 013051, 2016.

425.	Liu, Jiajia, Yuming Wang, Robertus Erdelyi, Rui Liu, Scott W. McIntosh, Tingyu Gou, Jun Chen, Kai Liu, Lijuan Liu, and Zonghao Pan, On the Magnetic and Energy Characteristics of Recurrent Homologous Jets from An Emerging Flux, Astrophys. J., 833, 150(11pp), 2016.
Abstract. In this paper, we present the detailed analysis of recurrent homologous jets originating from an emerging negative magnetic flux at the edge of an active region. The observed jets show multithermal features. Their evolution shows high consistence with the characteristic parameters of the emerging flux, suggesting that with more free magnetic energy, the eruptions tend to be more violent, frequent, and blowout-like. The average temperature, average electron number density, and axial speed are found to be similar for different jets, indicating that they should have been formed by plasmas from similar origins. Statistical analysis of the jets and their footpoint region conditions reveals a strong positive relationship between the footpoint region total 131 Å intensity enhancement and jets’ length/width. Stronger linearly positive relationships also exist between the total intensity enhancement/thermal energy of the footpoint regions and jets’ mass/kinetic/thermal energy, with higher cross-correlation coefficients. All the above results together confirm the direct relationship between the magnetic reconnection and the jets and validate the important role of magnetic reconnection in transporting large amounts of free magnetic energy into jets. It is also suggested that there should be more free energy released during the magnetic reconnection of blowout than of standard jet events. We acknowledge the use of data from the AIA and HMI instruments on board Solar Dynamics Observatory (SDO). SDO is a mission for NASA’s Living With a Star (LWS) program. We thank T. Wiegelmann for the NLFFF extrapolation codes and I. G. Hannah and E. P. Kontar for the DEM codes. J.L. acknowledges support from the China Postdoctoral Science Foundation (2015M580540). This work is also supported by grants from the Fundamental Research Funds for the Central Universities, CAS (Key Research Program KZZD-EW-01-4), NSFC (41131065), and MOEC (20113402110001). R.E. acknowledges the support received by the Chinese Academy of Sciences President’s International Fellowship Initiative, grant no. 2016VMA045, the Science and Technology Facility Council (STFC), UK and the Royal Society (UK). R.L. acknowledges the support from the Thousand Young Talents Program of China and NSFC 41474151.

424.	Mishra, Wageesh, Yuming Wang, and Nandita Srivastava, On Understanding the Nature of Collision of Coronal Mass Ejections Observed by STEREO, Astrophys. J., 831, 99(13pp), 2016.
Abstract.

423.	He, P., X. L. Gao, Quanming Lu, and S. Wang, He2+ heating via parametric instabilities of parallel propagating Alfven waves with an incoherent spectrum, Astrophys. J., 827, 64, 2016.

422.	Lijuan Liu,, Yuming Wang, Jingxiu Wang, Chenglong Shen, Pinzhong Ye, Quanhao, and Zhang, Rui Liu, and S. Wang, Why is a flare-rich active region CME-poor?, Astrophys. J., 826, 119 (10pp), 2016.

421.	Liu, Lijuan, Yuming Wang, Jingxiu Wang, Chenglong Shen, Pinzhong Ye, Rui Liu, Jun Chen, Quanhao Zhang, and S. Wang, Why is a flare-rich active region CME-poor?, Astrophys. J., 826, 119(10pp), 2016.
Abstract. Solar active regions (ARs) are the major sources of two of the most violent solar eruptions, namely flares and coronal mass ejections (CMEs). The largest AR in the past 24 years, NOAA AR 12192, which crossed the visible disk from 2014 October 17 to 30, unusually produced more than one hundred flares, including 32 M-class and 6 X-class ones, but only one small CME. Flares and CMEs are believed to be two phenomena in the same eruptive process. Why is such a flare-rich AR so CME-poor? We compared this AR with other four ARs; two were productive in both and two were inert. The investigation of the photospheric parameters based on the SDO/HMI vector magnetogram reveals that the flare-rich AR 12192, as with the other two productive ARs, has larger magnetic flux, current, and free magnetic energy than the two inert ARs but, in contrast to the two productive ARs, it has no strong, concentrated current helicity along both sides of the flaring neutral line, indicating the absence of a mature magnetic structure consisting of highly sheared or twisted field lines. Furthermore, the decay index above the AR 12192 is relatively low, showing strong constraint. These results suggest that productive ARs are always large and have enough current and free energy to power flares, but whether or not a flare is accompanied by a CME is seemingly related to (1) the presence of a mature sheared or twisted core field serving as the seed of the CME, or (2) a weak enough constraint of the overlying arcades. We would like to thank our anonymous referee for the careful review and helpful comments which helped us to revise this paper. We acknowledge the use of the data from the HMI and AIA instruments on board Solar Dynamics Observatory (SDO), the MDI and LASCO instruments on board Solar and Heliospheric Observatory (SOHO), and the Geostationary Operational Environmental Satellite (GOES). This work is supported by grants from NSFC (41131065, 41421063, 41274173, 41574165, 41222031, and 41474151), CAS (Key Research Program KZZD-EW-01-4), MOEC (20113402110001), MOST973 key project (2011CB811403), the fundamental research funds for the central universities, and the funds of the Thousand Young Talents Programme of China (R.L).

420.	Zhang, Quanhao, Yuming Wang, Youqiu Hu, and Rui Liu, Downward Catastrophe of Solar Magnetic Flux Ropes, Astrophys. J., 825, 109(8pp), 2016.
Abstract. 2.5-dimensional time-dependent ideal magnetohydrodynamic (MHD) models in Cartesian coordinates were used in previous studies to seek MHD equilibria involving a magnetic flux rope embedded in a bipolar, partially open background field. As demonstrated by these studies, the equilibrium solutions of the system are separated into two branches: the flux rope sticks to the photosphere for solutions at the lower branch but is suspended in the corona for those at the upper branch. Moreover, a solution originally at the lower branch jumps to the upper, as the related control parameter increases and reaches a critical value, and the associated jump is here referred to as an upward catastrophe. The present paper advances these studies in three aspects. First, the magnetic field is changed to be force-free; the system still experiences an upward catastrophe with an increase in each control parameter. Second, under the force-free approximation, there also exists a downward catastrophe, characterized by the jump of a solution from the upper branch to the lower. Both catastrophes are irreversible processes connecting the two branches of equilibrium solutions so as to form a cycle. Finally, the magnetic energy in the numerical domain is calculated. It is found that there exists a magnetic energy release for both catastrophes. The Ampèreʼs force, which vanishes everywhere for force-free fields, appears only during the catastrophes and does positive work, which serves as a major mechanism for the energy release. The implications of the downward catastrophe and its relevance to solar activities are briefly discussed. This research is supported by Grants from NSFC 41131065, 41574165, 41421063, 41474151, and 41222031, MOEC 20113402110001, CAS Key Research Program KZZD-EW- 01-4, and the Fundamental Research Funds for the Central Universities WK2080000077. R.L. acknowledges the support from the Thousand Young Talents Program of China.

419.	Hao, Y. F., Quanming Lu, X. L. Gao, and S. Wang, Ion dynamics at a rippled quasi-parallel shock:2-D hybrid simulations, Astrophys. J., 823, 7, 2016.

418.	Wang, H. Y., Quanming Lu, C. Huang, and S. Wang, The mechanisms of electron acceleration during multiple X line magnetic reconnection with a guide field, Astrophys. J., 821, 84, 2016.

417.	Rui Liu, Bernhard Kliem, Viacheslav S.Titov, Jun Chen, Yuming Wang, Haimin Wang, Chang Liu, Yan Xu, and Thomas Wiegelmann, Structure, Stability, and Evolution of Magnetic Flux Ropes from the Perspective of Magnetic Twist, Astrophys. J., 818, article id. 148, 2016.

416.	Liu, Rui, Bernhard Kliem, Viacheslav S. Titov, Jun Chen, Yuming Wang, Haimin Wang, Chang Liu, Yan Xu, and Thomas Wiegelmann, Structure, Stability, and Evolution of Magnetic Flux Ropes from the Perspective of Magnetic Twist, Astrophys. J., 818, 148(12pp), 2016. (SDO/HMI Science Nugget, http://hmi.stanford.edu/hminuggets/?p=1397;)
Abstract.

415.	Liu, Jiajia, Fang Fang, Yuming Wang, Scott W. McIntosh, Yuhong Fan, and Quanhao Zhang, On the Observation and Simulation of Solar Coronal Twin Jets, Astrophys. J., 817, 126(8pp), 2016.
Abstract. We present the first observation, analysis, and modeling of solar coronal twin jets, which occurred after a preceding jet. Detailed analysis on the kinetics of the preceding jet reveals its blowout-jet nature, which resembles the one studied in Liu et al. However, the erupting process and kinetics of the twin jets appear to be different from the preceding one. Lacking detailed information on the magnetic fields in the twin jet region, we instead use a numerical simulation using a three-dimensional (3D) MHD model as described in Fang et al., and find that in the simulation a pair of twin jets form due to reconnection between the ambient open fields and a highly twisted sigmoidal magnetic flux, which is the outcome of the further evolution of the magnetic fields following the preceding blowout jet. Based on the similarity between the synthesized and observed emission, we propose this mechanism as a possible explanation for the observed twin jets. Combining our observation and simulation, we suggest that with continuous energy transport from the subsurface convection zone into the corona, solar coronal twin jets could be generated in the same fashion addressed above. We acknowledge the use of data from the AIA instrument on board the Solar Dynamics Observatory (SDO) and the EUVI instrument on board the Solar TErrestrial RElations Observatory (STEREO). This work is supported by grants from the China Postdoctoral Science Foundation (2015M580540), MOST 873 key project (2011CB811403), CAS (Key Research Program KZZD-EW-01-4), NSFC (41131065 and 41121003), MOEC (20113402110001), and the fundamental research funds for the central universities. J.L. did part of this work when he was a student visitor at HAO and supported by the Chinese Scholarship Council (201306340034). F.F. is supported by NASA Grant NNX13AJ04A and the University of Colorados George Ellery Hale Postdoctoral Fellowship.

414.	Gou, Tingyu, Rui Liu, Yuming Wang, Kai Liu, Bin Zhuang, Jun Chen, Quanhao Zhang, and Jiajia Liu, Stereoscopic Observation of Slipping Reconnection in A Double Candle-Flame-Shaped Flare, Astrophys. J. Lett., 821, L28(7pp), 2016. (Highlighted by AAS, http://aasnova.org/2016/05/18/reconnection-on-the-sun/;)
Abstract. The 2011 January 28 M1.4 flare exhibits two side-by-side candle-flame-shaped flare loop systems underneath a larger cusp-shaped structure during the decay phase, as observed at the northwestern solar limb by the Solar Dynamics Observatory. The northern loop system brightens following the initiation of the flare within the southern loop system, but all three cusp-shaped structures are characterized by ∼10 MK temperatures, hotter than the archshaped loops underneath. The “Ahead” satellite of the Solar Terrestrial Relations Observatory provides a top view, in which the post-flare loops brighten sequentially, with one end fixed while the other apparently slipping eastward. By performing stereoscopic reconstruction of the post-flare loops in EUV and mapping out magnetic connectivities, we found that the footpoints of the post-flare loops are slipping along the footprint of a hyperbolic flux tube (HFT) separating the two loop systems and that the reconstructed loops share similarity with the magnetic field lines that are traced starting from the same HFT footprint, where the field lines are relatively flexible. These results argue strongly in favor of slipping magnetic reconnection at the HFT. The slipping reconnection was likely triggered by the flare and manifested as propagative dimmings before the loop slippage is observed. It may contribute to the late-phase peak in Fe XVI 33.5 nm, which is even higher than its main-phase counterpart, and may also play a role in the density and temperature asymmetry observed in the northern loop system through heat conduction. R.L. acknowledges the support from the Thousand Young Talents Program of China and NSFC 41474151. Y.W. acknowledges the support from NSFC 41131065 and 41574165. This work was also supported by NSFC 41421063, CAS Key Research Program KZZD-EW-01-4, and the fundamental research funds for the central universities.

413.	Yang, Z. W., C. Huang, Y. D. Liu, G.K. Parks, R.Wang, Quanming Lu, and H. D. Hu, Global explicit particle-in-cell simulations of the nonstationary bow shock and magnetosphere, Astrophys. J. Supp., 225, 13, 2016.

412.	Wang, Yuming, Zhenjun Zhou, Jie Zhang, Kai Liu, Rui Liu, Chenglong Shen, and Phillip C. Chamberlin, Thermodynamic Spectrum of Solar Flares Based on SDO/EVE Observations: Techniques and First Results, Astrophys. J. Supp., 223, 4(22pp), 2016.
Abstract. The Solar Dynamics Observatory (SDO)/EUV Variability Experiment (EVE) provides rich information on the thermodynamic processes of solar activities, particularly on solar flares. Here, we develop a method to construct thermodynamic spectrum (TDS) charts based on the EVE spectral lines. This tool could potentially be useful for extreme ultraviolet (EUV) astronomy to learn about the eruptive activities on distant astronomical objects. Through several cases, we illustrate what we can learn from the TDS charts. Furthermore, we apply the TDS method to 74 flares equal to or greater than the M5.0 class, and reach the following statistical results. First, EUV peaks are always behind the soft X-ray (SXR) peaks and stronger flares tend to have faster cooling rates. There is a power-law correlation between the peak delay times and the cooling rates, suggesting a coherent cooling process of flares from SXR to EUV emissions. Second, there are two distinct temperature drift patterns, called Type I and Type II. For Type I flares, the enhanced emission drifts from high to low temperature like a quadrilateral, whereas for Type II flares the drift pattern looks like a triangle. Statistical analysis suggests that Type II flares are more impulsive than Type I flares. Third, for late-phase flares, the peak intensity ratio of the late phase to the main phase is roughly correlated with the flare class, and the flares with a strong late phase are all confined. We believe that the re-deposition of the energy carried by a flux rope, which unsuccessfully erupts out, into thermal emissions is responsible for the strong late phase found in a confined flare. Furthermore, we show the signatures of the flare thermodynamic process in the chromosphere and transition region in the TDS charts. These results provide new clues to advance our understanding of the thermodynamic processes of solar flares and associated solar eruptions, e.g., coronal mass ejections. We acknowledge use of data from the SDO, STEREO, SOHO,and GOES spacecraft. SDO is a mission of NASAʼs Living With a Star Program, STEREO is the third mission in NASAʼs Solar Terrestrial Probes program, and SOHO is a mission of international cooperation between ESA and NASA. The TDS charts for all the events involved in this study could be found at http://space.ustc.edu.cn/dreams/shm/tds (the MEGS-A-only TDS) and http://space.ustc.edu.cn/dreams/shm/tds-c09 (the extended TDS). This work is supported by grants from the NSFC (41131065, 41574165, 41421063, 41274173, 41222031, 41404134, and 41474151), CAS (Key Research Program KZZD-EW-01 and 100-Talent Program), MOST 973 key project (2011CB811403), and the fundamental research funds for the central universities.

411.	XIONG Ming, LIU Ying, LIU Hao, LI Baoquan, ZHENG Jianhua, ZHANG Cheng, XIA Lidong, ZHANG Hongxin, RAO Wei, CHEN Changya, SUN Weiying, WU Xia, DENG Yuanyong, HE Han, JIANG Bo, WANG Yuming, WANG Chuanbing, SHEN Chenglong, ZHANG Haiying, ZHANG Shenyi, YANG Xuan, SANG Peng, and WU Ji, Overview of the Solar Polar Orbit Telescope Project for Space Weather Mission, Chinese J. Space Sci., 36, 245-266, 2016.

410.	Gao, X. L., Quanming Lu, J. Bortnik, W. Li, L. J. Chen, and S. Wang, Generation of multi-band chorus by lower band cascade in the earth's magnetosphere, Geophys. Res. Lett., 43, 2343-2350, 2016.

409.	Gao, Z. L., Su, Z. P., Zhu, H., Xiao, F. L., Zheng, H. N., Wang, Y. M., Shen, C., and Wang, S., Intense low-frequency chorus waves observed by Van Allen Probes: Fine structures and potential effect on radiation belt electrons, Geophys. Res. Lett.*, 43, 967-977, 2016.

408.	Wang, B., Su, Z. P., Zhang, Y., Shi, S. W., and Wang, G., Nonlinear Landau resonant scattering of near-equatorially mirroring radiation belt electrons by oblique EMIC waves, Geophys. Res. Lett.*, 43, 3628-3636, 2016.

407.	Yang, C., Su, Z. P., Xiao, F. L., Zheng, H. N., Wang, Y. M., Wang, S., Spence, H. E. Reeves, G. D., Baker, D. N., Blake, J. B., and Funsten, H. O., Rapid flattening of butterfly pitch-angle distributions of radiation belt electrons by whistler-mode chorus, Geophys. Res. Lett.*, 43, 8339-8347, 2016.

406.	Xiao, F. L., Zhou, Q. H., Su, Z. P., He, Z. G., Yang, C., Liu, S., He, Y. H., and Gao, Z. L., Explaining occurrences of auroral kilometric radiation in Van Allen radiation belts, Geophys. Res. Lett., 43, 11971-11978, 2016.

405.	Gao, Zhonglei, Zhenpeng Su, Hui Zhu, Fuliang Xiao, Huinan Zheng, Yuming Wang, Chao Shen, and Shui Wang, Intense low-frequency chorus waves observed by Van Allen Probes: Fine structures and potential effect on radiation belt electrons, Geophys. Res. Lett., 43, 967-977, 2016.

404.	Chang Yang, Zhenpeng Su, Fuliang Xiao, Huinan Zheng, Yuming Wang, Shui Wang, H. E. Spence, G. D. Reeves, D. N. Baker, J. B. Blake, and H. O. Funsten, Rapid flattening of butterfly pitch-angle distributions of radiation belt electrons by whistler-mode chorus, Geophys. Res. Lett., 43, 8339-8347, 2016.

403.	Zhonglei Gao, Zhenpeng Su, Hui Zhu, Fuliang Xiao, Huinan Zheng, Yuming Wang, Chao Shen, and Shui Wang, Intense low-frequency chorus waves observed by Van Allen Probes: Fine structures and potential effect on radiation belt electrons, Geophys. Res. Lett., , 2016.

402.	Qiu, Q, H. G. Yang, Quanming Lu, Z. J. Hu, D. S. Han, and Q. Wang, Orientation variation of dayside auroral arc alignments obtained from all-sky observation at Yellow River Station, Svalbard, J. Atoms. Sol.-Terres. Phys., 142, 20-24, 2016.

401.	Chen, L. J., J. C. Sun, Quanming Lu, X. L. Gao, Z. Y. Xia, and Z. Zhima, Generation of magnetosonic waves over a continuous spectrum, J. Geophys. Res. - Space Phys., 121, 1137-1147, 2016.

400.	Hao, Y. F., B. Lembege, Quanming Lu, and Fan Guo, Formation of downstream high speed jets by a rippled nonstationary quasi-parallel shock: 2-D hybrid simulations, J. Geophys. Res. - Space Phys., 121, 2080, 2016.

399.	Lu, S, A. Artemyev, V. Angelopoulos, Quanming Lu, and J. Liu, On the current density reduction ahead of dipolarization fronts, J. Geophys. Res. - Space Phys., 121, 4269-4278, 2016.

398.	Gao,X. L., D. Mourenas, W. Li, A. V. Artemyev, Q. M. Lu, X. Tao, and S. Wang, Observational evidence of generation mechanisms for very oblique lower band chorus using THEMIS waveform data, J. Geophys. Res. - Space Phys., 121, 6732-6748, 2016.

397.	Shan, L. C., C. Mazelle, M. Delva, Quanming Lu, Y. S. Ge, A. M. Du, and T. L. Zhang, Characteristics of quasi-monochromatic ULF waves in the Venusian foreshock, J. Geophys. Res. - Space Phys., 121, 7385-7397, 2016.

396.	Wu, M. Y., Quanming Lu, M. Volwerk, Z. Voros, X. Y. Ma, and S. Wang, Current sheet flapping motion in the tailward flow of magnetic reconnection, J. Geophys. Res. - Space Phys., 121, 7817-7827, 2016.

395.	Wang, R. S., Quanming Lu, R. Nakamura, C. Huang, X. Li, M. Y. Wu, A. M. Du, X. L. Gao, and S. Wang, The electrostatic and electromagnetic fluctuations detected inside magnetic flux ropes during magnetic reconnection, J. Geophys. Res. - Space Phys., 121, 9473-9482, 2016.

394.	Zhao, Y, R. S. Wang, Quanming Lu, A. M. Du, Z. H. Yao, and M. Y. Wu, Coalescence of magnetic flux ropes observed in the tailward high speed flows, J. Geophys. Res. - Space Phys., 121, 10898-10909, 2016.

393.	Lu, S., Y. Lin, V. Angelopoulos, A.V.Artemyev, P. L. Pritchett, Quanming Lu, and X. Y. Wang, Hall effect control of magnetotail dawn-dusk asymmetry: A three-dimensional global hybrid simulation, J. Geophys. Res. - Space Phys., 121, 11882-11895, 2016.

392.	Su, Z. P., Gao, Z. L., Zhu, H., Li, W., Zheng, H. N., Wang, Y. M., Wang, S., Spence, H. E., Reeves, G. D., Baker, D. N., Blake, J. B., Funsten, H. O., and Wygant, J. R., Nonstorm time dropout of radiation belt electron fluxes on 24 September 2013, J. Geophys. Res. - Space Phys., 121, 6400-6416, 2016.

391.	Tang, C. L., Zhang, J.-C., Reeves, G. D., Su, Z. P., Baker, D. N., Spence, H. E., Funsten, H. O., Blake, J. B., and Wygant, J. R., Prompt enhancement of the Earth's outer radiation belt due to substorm electron injections, J. Geophys. Res. - Space Phys., 121, 11826-11838, 2016.

390.	Guo, Jianpeng, Fengsi Wei, Xueshang Feng, Jeffrey M. Forbes, Yuming Wang, Huixin Liu, Weixing Wan, Zhiliang Yang, and Chaoxu Liu, Prolonged multiple excitation of large-scale traveling atmospheric disturbances (TADs) by successive and interacting coronal mass ejections, J. Geophys. Res. - Space Phys., 121, 2662-2668, 2016.
Abstract.

389.	Zhenpeng Su, Zhonglei Gao, Hui Zhu, Wen Li, Huinan Zheng, Yuming Wang, Shui Wang, H. E. Spence, G. D. Reeves, D. N. Baker, J. B. Blake, H. O. Funsten, and J. R. Wygant, Nonstorm time dropout of radiation belt electron fluxes on 24 September 2013, J. Geophys. Res. - Space Phys., 121, 6400-6416, 2016.

388.	Wang, Yuming, Quanhao Zhang, Jiajia Liu, Chenglong Shen, Fang Shen, Zicai Yang, T. Zic, B. Vrsnak, D. F. Webb, Rui Liu, S. Wang, Jie Zhang, Q. Hu, and B. Zhuang, On the Propagation of a Geoeffective Coronal Mass Ejection during March 15 - 17, 2015, J. Geophys. Res. - Space Phys., 121, 7423-7434, 2016.
Abstract. The largest geomagnetic storm so far, called 2015 St. Patrick’s Day event, in the solar cycle 24 was produced by a fast coronal mass ejection (CME) originating on 15 March 2015. It was an initially west-oriented CME and expected to only cause a weak geomagnetic disturbance. Why did this CME finally cause such a large geomagnetic storm? We try to find some clues by investigating its propagation from the Sun to 1 AU. First, we reconstruct the CME’s kinematic properties in the corona from the SOHO and Solar Dynamics Observatory imaging data with the aid of the graduated cylindrical shell model. It is suggested that the CME propagated to the west ∼33∘±10∘ away from the Sun-Earth line with a speed of about 817 km s−1 before leaving the field of view of the SOHO/Large Angle and Spectrometric Coronagraph (LASCO) C3 camera. A magnetic cloud (MC) corresponding to this CME was measured in situ by the Wind spacecraft 2 days after the CME left LASCO’s field of view. By applying two MC reconstruction methods, we infer the configuration of the MC as well as some kinematic information, which implies that the CME possibly experienced an eastward deflection on its way to 1 AU. However, due to the lack of observations from the STEREO spacecraft, the CME’s kinematic evolution in interplanetary space is not clear. In order to fill this gap, we utilize numerical MHD simulation, drag-based CME propagation model (DBM) and the model for CME deflection in interplanetary space (DIPS) to recover the propagation process, especially the trajectory, of the CME from 30RS to 1 AU under the constraints of the derived CME’s kinematics near the Sun and at 1 AU. It is suggested that the trajectory of the CME was deflected toward the Earth by about 12∘, consistent with the implication from the MC reconstruction at 1 AU. This eastward deflection probably contributed to the CME’s unexpected geoeffectiveness by pushing the center of the initially west-oriented CME closer to the Earth. We acknowledge the use of the data from SOHO, SDO, and Wind spacecraft and the H𝛼 images from Kanzelhoehe Observatory. SOHO is a mission of international cooperation between ESA and NASA, and SDO is a mission of NASA’s Living With a Star Program. We also acknowledge the discussion of the event with T. Berger, N. Gopalswamy, P. Hess, Y. Liu, K. Marubashi, C. Moestl, T. Rollett, M. Temmer, C.-C. Wu, and S. Yashiro under the ISEST program. We thank the anonymous referees for their constructive comments. This work is supported by grants from NSFC (41131065 and 41421063), CAS (Key Research Program KZZD-EW-01 and 100-Talent Program), and the fundamental research funds for the central universities. Y.W. is also supported by NSFC41574165, C.S. by NSFC41274173, F.S. and Z.Y. by NSFC41474152 and MOST 973 key project 2012CB825601, and R.L. by NSFC 41222031. B.V. and T.Z. acknowledge the financial support by the Croatian Science Foundation under the project 6212 “Solar and Stellar Variability.”

387.	Wang, Yuming, Bin Zhuang, Qiang Hu, Rui Liu, Chenglong Shen, and Yutian Chi, On the twists of interplanetary magnetic flux ropes observed at 1 AU, J. Geophys. Res. - Space Phys., 121, 9316-9339, doi:10.1002/2016JA023075, 2016. (Editor's Highlight: http://agupubs.onlinelibrary.wiley.com/agu/article/10.1002/2016JA023075/editor-highlight/)
Abstract. Magnetic flux ropes (MFRs) are one kind of fundamental structures in the solar/space physics and involved in various eruption phenomena. Twist, characterizing how the magnetic field lines wind around a main axis, is an intrinsic property of MFRs, closely related to the magnetic free energy and stableness. Although the effect of the twist on the behavior of MFRs had been widely studied in observations, theory, modeling, and numerical simulations, it is still unclear how much amount of twist is carried by MFRs in the solar atmosphere and in heliosphere and what role the twist played in the eruptions of MFRs. Contrasting to the solar MFRs, there are lots of in situ measurements of magnetic clouds (MCs), the large-scale MFRs in interplanetary space, providing some important information of the twist of MFRs. Thus, starting from MCs, we investigate the twist of interplanetary MFRs with the aid of a velocity-modified uniform-twist force-free flux rope model. It is found that most of MCs can be roughly fitted by the model and nearly half of them can be fitted fairly well though the derived twist is probably overestimated by a factor of 2.5. By applying the model to 115 MCs observed at 1 AU, we find that (1) the twist angles of interplanetary MFRs generally follow a trend of about 0.6 l/R radians, where l/R is the aspect ratio of a MFR, with a cutoff at about 12𝜋 radians AU−1, (2) most of them are significantly larger than 2.5𝜋 radians but well bounded by 2 l/R radians, (3) strongly twisted magnetic field lines probably limit the expansion and size of MFRs, and (4) the magnetic field lines in the legs wind more tightly than those in the leading part of MFRs. These results not only advance our understanding of the properties and behavior of interplanetary MFRs but also shed light on the formation and eruption of MFRs in the solar atmosphere. A discussion about the twist and stableness of solar MFRs are therefore given. We acknowledge the use of the data from Wind spacecraft. We thank Stephen Kahler from AFRL, USA, for providing the data about the magnetic field line lengths inferred from energetic electron events. We also thank the anonymous referees for their useful comments. The model developed in this work can be run and tested online at http://space.ustc.edu.cn/dreams/ mc_fitting/. This work is supported by the grants from NSFC (41131065, 41574165, 41421063, 41274173, and 41474151), CAS (Key Research ProgramKZZD-EW-01-4), MOEC (20113402110001), and the fundamental research funds for the central universities.

386.	Zhenpeng Su, Zhonglei Gao, Hui Zhu, Wen Li, Huinan Zheng, Yuming Wang, Shui Wang, H. E. Spence, G. D. Reeves, D. N. Baker, J. B. Blake, and J.R. Wygant, Nonstorm time dropout of radiation belt electron fluxes on 24 September 2013, J. Geophys. Res. - Space Phys., , 2016.

385.	Zhenpeng Su, Hui Zhu, Fuliang Xiao, Qiugang Zong, Xuzhi Zhou, Huinan Zheng, Yuming Wang, Shui Wang, Y.-X. Hao, Zhonglei Gao, Zhaoguo He, D. N. Baker, H. E. Spence, G. D. Reeves, J. B. Blake, and J.R. Wygant, Ultra-low-frequency wave-driven diffusion of radiation belt relativistic electrons, Nat. Comm., , 2016.

384.	Yuri Y. Shprits, Alexander Y. Drozdov, Maria Spasojevic, Adam C. Kellerman, Maria E. Usanova, Mark J. Engebretson, Oleksiy V. Agapitov, Irina S. Zhelavskaya, Tero J. Raita, Harlan E. Spence, Daniel N. Baker, Hui Zhu, and Nikita A. Aseev, Wave-induced loss of ultra-relativistic electrons in the Van Allen radiation belts, Nat. Comm., , 2016.

383.	Wang, R. S., Quanming Lu, R. Nakamura, C. Huang, A. M. Du, F. Guo, W. L. Teh, M. Y. Wu, S. Lu, and S. Wang, Coalescence of magnetic flux ropes in the ion diffusion region of magnetic reconnection, Nat. Phys., 12, 263-267, 2016.

382.	Sun, J. C., X. L. Gao, L. J. Chen, Quanming Lu, X. Tao, and S. Wang, A parametric study for the generation of ion Bernstein modes from a discrete spectrum to a continuous one in the inner magnetosphere. I. Linear theory, Phys. Plasmas, 23, 022901, 2016.

381.	Sun, J. C., X. L. Gao, Quanming Lu, L. J. Chen, X. Tao, and S. Wang, A parametric study for the generation of ion Bernstein modes from a discrete spectrum to a continuous one in the inner magnetosphere. II. Particle-in-cell simulations, Phys. Plasmas, 23, 022902, 2016.

380.	Fan, F. B, C. Huang, Quanming Lu, J. L. Xie, and S. Wang, The structures of magnetic islands formed during collisionless magnetic reconnections in a force free current sheet, Phys. Plasmas, 23, 112106, 2016.

379.	Zhang, Quanhao, Yuming Wang, Rui Liu, Chenglong Shen, Min Zhang, Tingyu Gou, Jiajia Liu, Kai Liu, Zhenjun Zhou, and Shui Wang, Damped large amplitude oscillations in a solar prominence and a bundle of coronal loops, Res. Astron. Astrophys., 16, 167(10pp), 2016.
Abstract. We investigate the evolutions of two prominences (P1, P2) and two bundles of coronal loops (L1, L2), observed with SDO/AIA near the east solar limb on 2012 September 22. It is found that there were large-amplitude oscillations in P1 and L1 but no detectable motions in P2 and L2. These transverse oscillations were triggered by a large-scale coronal wave, originating from a large flare in a remote active region behind the solar limb. By carefully comparing the locations and heights of these oscillating and non-oscillating structures, we conclude that the propagating height of the wave is between 50 Mm and 130 Mm. The wave energy deposited in the oscillating prominence and coronal loops is at least of the order of 10^28 erg. Furthermore, local magnetic field strength and Alfv´en speeds are derived from the oscillating periods and damping time scales, which are extracted from the time series of the oscillations. It is demonstrated that oscillations can be used in not only coronal seismology, but also to reveal the properties of the wave. Acknowledgements. This research is supported by the National Natural Science Foundation of China (Grant Nos. 41131065, 41574165, 41421063 and 41304134), MOEC (20113402110001), CAS Key Research Program (KZZD-EW-01-4), the fundamental research funds for the central universities (WK2080000077), and the foundation for Young Talents in College of Anhui Province (2013SQRL044ZD). The CME catalog used to obtain the kinetic parameters of the relevant CME is generated and maintained at the CDAW Data Center by NASA and The Catholic University of America in cooperation with the Naval Research Laboratory. SOHO is a project of international cooperation between ESA and NASA.

378.	Chi, Yutian, Chenglong Shen, Yuming Wang, Mengjiao Xu, Pinzhong Ye, and Shui Wang, Statistical study of the interplanetary coronal mass ejections from 1996 to 2015, Sol. Phys., 291*, 2419-2439, 2016.
Abstract. We establish a catalog of interplanetary coronal mass ejections (ICMEs) during the period from 1995 to 2015 using the in-situ observations from the Wind and ACE spacecraft. Based on this catalog, we extend the statistical properties of ICMEs to the maximum phase of Solar Cycle 24.We confirm previous results that the yearly occurrence frequencies of ICMEs and shocks, the ratios of ICMEs driving shocks are correlated with the sunspot numbers. For the magnetic cloud (MC), we confirm that the yearly occurrence frequencies of MCs do not show any correlation with sunspot numbers. The highest MC ratio of ICME occurred near the solar minimum. In addition, we analyzed the yearly variation of the ICME parameters. We found that the ICME velocities, the magnetic-field strength, and their related parameters are varied in pace with solar-cycle variation. At the solar maximum, ICMEs move faster and carry a stronger magnetic field. By comparing the parameters between MCs and non-MC ejecta, we confirm the result that the magnetic-field intensities of MC are higher than those in non-MC ejecta. Furthermore, we also discuss the forward shocks driven by ICMEs. We find that one half of the ICMEs have upstream shocks and ICMEs with shocks have faster speed and higher magnetic-field strength than the ICMEs without shocks. The magnetic-field parameters and solar-wind plasma parameters in the shock sheath regions are higher than those in the ejecta regions of ICMEs from a statistical point of view. We acknowledge the use of the data from Wind and ACE spacecraft. We also thank the Harvard-Smithsonian Center for Astrophysics Interplanetary Shock Database (supported by NASA grant number NNX13AI75G) for using their shock parameters. We thank the anonymous referee for the constructive comments. This work is supported by grants from MOST 973 key project (2011CB811403), CAS (Key Research Program KZZD-EW-01 and 100-Talent Program), NSFC (41131065, 41121003, 41274173, 41222031 and 41404134), the fundamental research funds for the central universities and the Specialized Research Fund for State Key Laboratories.

377.	Shen, Fang, Yuming Wang, Chenglong Shen, and Xueshang Feng, Turn on the super-elastic collision nature of coronal mass ejections through low approaching speed, Sci. Rep.*, 6, 19576, 2016.
Abstract. It has been proved from the observations and numerical simulations that the collision between solar coronal mass ejections (CMEs), the largest plasmoids in the heliosphere, could be super-elastic. This finding suggests that the CMEs’ magnetic energy and thermal energy could be converted into kinetic energy through a more efficient way. However CME collisions are not always super-elastic, which means that this distinct property of plasmoids is probably excited conditionally. As the first attempt, we carry out a series of three-dimensional numerical experiments, and establish a diagram showing the dependence of the collision nature on the CME speed and k-number, the ratio of the CME’s kinetic energy to the CME’s total energy. It is found that the super-elastic nature of CMEs appears at the relatively low approaching speed, and most of the previous case studies are in agreement with this diagram. Our study firmly advances the understanding of the super-elastic property of plasmoids, and does give us new clues to deeply understand why and how the magnetic energy and/or thermal energy of the colliding plasmoids can be converted into kinetic energy in such an efficient way. We acknowledge the use of the data from Wind spacecraft, and thank the anonymous referees for valuable comments. This work is supported by the grants from MOST 973 key project (2012CB825601, 2011CB811403), the CAS knowledge innovation program (KZZD-EW-01-4), the NSFC projects (41231068, 41174150, 41274192, 41474152, 41131065, 41121063, 41574165 and 41274173), the Specialized Research Fund for State Key Laboratories and the fundamental research funds for the central universities.

376.	Liu, Rui, Jun Chen, Yuming Wang, and Kai Liu, Investigating Energetic X-Shaped Flares on the Outskirts of A Solar Active Region, Sci. Rep., 6, 34021, 2016.
Abstract. Typical solar flares display two quasi-parallel, bright ribbons on the chromosphere. In between is the polarity inversion line (PIL) separating concentrated magnetic fluxes of opposite polarity in active regions (ARs). Intriguingly a series of flares exhibiting X-shaped ribbons occurred at the similar location on the outskirts of NOAA AR 11967, where magnetic fluxes were scattered, yet three of them were alarmingly energetic. The X shape, whose center coincided with hard X-ray emission, was similar in UV/EUV, which cannot be accommodated in the standard flare model. Mapping out magnetic connectivities in potential fields, we found that the X morphology was dictated by the intersection of two quasi-separatrix layers, i.e., a hyperbolic flux tube (HFT), within which a separator connecting a double null was embedded. This topology was not purely local but regulated by fluxes and flows over the whole AR. The nonlinear force-free field model suggested the formation of a current layer at the HFT, where the current dissipation can be mapped to the X-shaped ribbons via field-aligned heat conduction. These results highlight the critical role of HFTs in 3D magnetic reconnection and have important implications for astrophysical and laboratory plasmas. We thank the SDO team for the vector magnetic field and EUV imaging data, P.W. Schuck for the flow tracking code, T. Wiegelmann for the NLFFF code, X. Cheng for helpful comments. R.L. acknowledges the support from the Thousand Young Talents Program of China and NSFC 41474151. Y.W. acknowledges the support from NSFC 41131065 and 41574165. This work was also supported by NSFC 41421063, CAS Key Research Program KZZD-EW-01-4, and the fundamental research funds for the central universities.

2015 Top

375.	Liang, Y. H., G. Y. Hu, P. Yuan, Y. L. Wang, B. Zhao, F. L. Song, Quanming Lu, J. Zheng, , and Zheng Jian, Temporal evolutions of the plasma density and temperature of laser-produced plasma expansion in an external transverse magnetic field, Acta Physica Sinica, 64, 125204, 2015.

374.	Haimin Wang, Wenda Cao, Chang Liu, Yan Xu, Rui Liu, Zhicheng Zeng, Jongchul Chae, and Haisheng Ji, Witnessing magnetic twist with high-resolution observation from the 1.6-m New Solar Telescope, Nature Communications, 6, 7008, 2015.

373.	Cui, Y. Q., Z. M. Sheng, Quanming Lu, Y. T. Li, and J. Zhang, Two-stage acceleration of interstellar ions driven by high-energy lepton plasma flows, SCIENCE CHINA-Physics, Mechanics & Astronomy, 58, 105201, 2015.

372.	Jiajia Liu, Fuming Wan, Chenglong Shen, Kai Liu, Zonghao Pan, and S. Wang, A SOLAR CORONAL JET EVENT TRIGGERS A CORONAL MASS EJECTION, Astrophys. J., 813, 115, 2015.

371.	C. Zhu, R. Liu, D. Alexander, X. Sun, and R.T. J. McAteer, Complex Flare Dynamics Initiated by a Filament-Filament Interaction, Astrophys. J., 813, 60, 2015.

370.	Liu, Jiajia, Yuming Wang, Chenglong Shen, Kai Liu, Zonghao Pan, and S. Wang, A Solar Coronal Jet Event Triggers A Coronal Mass Ejection, Astrophys. J., 813, 115(6pp), 2015. (Highlighted by AAS, http://aasnova.org/2015/11/18/eruptions-from-the-sun/)
Abstract. In this paper, we present multi-point, multi-wavelength observations and analysis of a solar coronal jet and coronal mass ejection (CME) event. Employing the GCS model, we obtained the real (three-dimensional) heliocentric distance and direction of the CME and found it to propagate at a high speed of over 1000 km s−1. The jet erupted before the CME and shared the same source region. The temporal and spacial relationship between these two events lead us to the possibility that the jet triggered the CME and became its core. This scenario hold the promise of enriching our understanding of the triggering mechanism of CMEs and their relations to coronal large-scale jets. On the other hand, the magnetic field configuration of the source region observed by the Solar Dynamics Observatory (SDO)/HMI instrument along with the off-limb inverse Y-shaped configuration observed by SDO/ AIA in the 171 Å passband provide the first detailed observation of the three-dimensional reconnection process of a large-scale jet as simulated in Pariat et al. The eruption process of the jet highlights the importance of filament-like material during the eruption of not only small-scale X-ray jets, but likely also of large-scale EUV jets. Based on our observations and analysis, we propose the most probable mechanism for the whole event, with a blob structure overlaying the three-dimensional structure of the jet, to describe the interaction between the jet and the CME. We acknowledge the use of data from the Solar Dynamics Observatory (SDO), the Solar TErrestrial RElations Observatory (STEREO) and the Solar and Heliospheric Observatory (SOHO). Animation M1 was generated using the “JHelioviewer” tool (http://www.helioviewer.org). This work is supported by grants from NSFC (41131065, 41121003, and 41574165), CAS (Key Research Program KZZD-EW-01-4), MOST 973 key project (2011CB811403), MOEC (20113402110001), and the fundamental research funds for the central universities. The research leading to these results has also received funding from NSFC 41274173, 41404134 and 41304145.

369.	L Feng, Y Wang, F Shen, C Shen, B Inhester, L Lu, and W Gan, Why does the apparent mass of a coronal mass ejection increase?, Astrophys. J., 812 (1), 70, 2015.

368.	Feng, L., Yuming Wang, Fang Shen, Chenglong Shen, Bernd Inhester, Lei Lu, and Weiqun Gan, Why Does the Apparent Mass of a Coronal Mass Ejection Increase?, Astrophys. J., 812*, 70(12pp), 2015.
Abstract.

367.	Yang,Z. W., Y. D. Liu, J. D. Richardson, Quanming Lu, C. Huang, and R. Wang, Impact of pickup ions on the shock front nonstationarity and energy dissipation of the heliospheric termination shock: two-dimensional full particle simulations and comparison with Voyager 2 observations, Astrophys. J., 809, 28, 2015.

366.	Wu, M. Y., Y. F. Hao, Quanming Lu, C. Huang, F. Guo, and S. Wang, The role of large amplitude upstream low-frequency waves in the generation of superthermal ions at a quasi-parallel collisionless shock: Cluster Observations, Astrophys. J., 808, 2, 2015.

365.	Wang, C. B., A Scenario for the Fine Structures of Solar Type IIIb Radio Bursts Based on Electron Cyclotron Maser Emission, Astrophys. J., 806, 34, 2015.

364.	Liu, Jiajia, Scott W. McIntosh, Ineke De Moortel, and Yuming Wang, On the Parallel and Perpendicular Propagating Motions Visible in Polar Plumes: An Incubator For (Fast) Solar Wind Acceleration?, Astrophys. J., 806, 273(7pp), 2015.

363.	Song, H. Q., J. Zhang, Y. Chen, X. Cheng, G. Li, and Y. M. Wang, First taste of hot channel in interplanetary space, Astrophys. J., 803, 96(8pp), 2015.

362.	K Liu, Y Wang, J Zhang, X Cheng, R Liu, and C Shen, Extremely Large EUV Late Phase of Solar Flares, Astrophys. J., 802 (1), 35, 2015.

361.	Liu, Kai, Wang, Yuming, Zhang, Jie, Cheng, Xin, Liu, Rui, and Shen, Chenglong, Extremely Large EUV Late Phase of Solar Flares, Astrophys. J., 802, 35, 2015.

360.	Liu, Kai, Yuming Wang, Jie Zhang, Xin Cheng, Rui Liu, and Chenglong Shen, Extremely Large EUV Late Phase of Solar Flares, Astrophys. J., 802, 35(9pp), 2015.

359.	NA DENG, XIN CHEN, CHANG LIU, JU JING, ALEXANDRA TRITSCHLER, KEVIN P. REARDON, DEREK A. LAMB, CRAIG E. DEFOREST, CARSTEN DENKE, SHUO WANG, RUI LIU, and HAIMIN WANG, CHROMOSPHERIC RAPID BLUESHIFTED EXCURSIONS OBSERVED WITH IBIS AND THEIR ASSOCIATION WITH PHOTOSPHERIC MAGNETIC FIELD EVOLUTION, Astrophys. J., 799, 219, 2015.

358.	Chang Liu, Na Deng, Rui Liu, Jeongwoo Lee, Etienne Pariat, Thomas Wiegelmann, Yang Liu, Lucia Kleint, and Haimin Wang, A Circular-Ribbon Solar Flare Following An Asymmetric Filament Eruption, Astrophys. J. Lett., 812, L19, 2015.

357.	Song, Hongqiang, Yao Chen, Jie Zhang, Xin Cheng, Bing Wang, Qiang Hu, Gang Li, and Yuming Wang, EVIDENCE OF THE SOLAR EUV HOT CHANNEL AS A MAGNETIC FLUX ROPE FROM REMOTE-SENSING AND IN-SITU OBSERVATIONS, Astrophys. J. Lett., 808, L15(6pp), 2015.

356.	Xudong Sun, Monica Bobra, Todd Hoeksema, Yang Liu, Yan Li, Chenglong Shen, Sebastien Couvidat, Aimee Norton, and George H. Fisher, Why Is the Great Solar Active Region 12192 Flare-Rich But CME-Poor?, Astrophys. J. Lett., 804, L28, 2015.

355.	Zhao, G. Q.; Wu, D. J.; Wang, C. B., A study of line widths and kinetic parameters of ions in the solar corona, Astrophys. & Space Sci., 353, 373, 2015.

354.	Wang, H. Y., C. Huang, Quanming Lu, and S. Wang, On the gradient of the electron pressure in anti-parallel magnetic reconnection, Chinese Phys. Lett., 32, 045201, 2015.

353.	He, P., X. L. Gao, Quanming Lu, and J. S. Zhao, Parametric instabilities of parallel propagating circularly polarized Alfven waves: One-dimensional hybrid simulations, Chinese Phys. Lett., 32, 115202, 2015.

352.	Su, Zhenpeng, Hui Zhu, Fuliang Xiao, Huinan Zheng, Yuming Wang, Chao Shen, Min Zhang, Shui Wang, C. A. Kletzing, W. S. Kurth, G. B. Hospodarsky, H. E. Spence, G. D. Reeves, H. O. Funsten, J. B. Blake, D. N. Baker, and J. R. Wygant, Disappearance of plasmaspheric hiss following interplanetary shock, Geophys. Res. Lett., 42(9), 3129-3140, 2015.

351.	Zhu, Hui, Zhenpeng Su, Fuliang Xiao, Huinan Zheng, Yuming Wang, Chao Shen, Tao Xian, Shui Wang, C. A. Kletzing, W. S. Kurth, G. B. Hospodarsky, H. E. Spence, G. D. Reeves, H. O. Funsten, J. B. Blake, and D. N. Baker, Plasmatrough exohiss waves observed by Van Allen Probes: Evidence for leakage from plasmasphere and resonant scattering of radiation belt electrons, Geophys. Res. Lett., 42(4), 1012-1019, 2015.

350.	Huang, C., Quanming Lu, F. Guo, M. Y. Wu, A. M. Du, and S. Wang, Magnetic islands formed due to the Kelvin-Helmholz instability in the outflow region of collisionless magnetic reconnection, Geophys. Res. Lett., 42, 7282-7286, 2015.

349.	Li,X. X., X. Tao, Quanmin Lu, and L. Dai, Bounce resonance diffusion coefficients for spatially confined waves, Geophys. Res. Lett., 42, 9591-9599, 2015.

348.	Zhu, H., Su, Z. P., Xiao, F. L., Zheng, H. N., Wang, Y. M., Shen, C., Xian, T., Wang, S., Kletzing, C. A., Kurth, W. S., Hospodarsky, G. B., Spence, H. E., Reeves, G. D. Funsten, H. O., Blake, J. B., and Baker, D. N., Plasmatrough exohiss waves observed by Van Allen Probes: Evidence for leakage from plasmasphere and resonant scattering of radiation belt electrons, Geophys. Res. Lett.*, 42, 1012-1019, 2015.

347.	Su, Z. P., Zhu, H., Xiao, F. L., Zheng, H. N., Wang, Y. M., Shen, C., Zhang, M., Wang, S., Kletzing, C. A., Kurth, W. S., Hospodarsky, G. B., Spence, H. E. Reeves, G. D., Funsten, H. O., Blake, J. B., and Baker, D. N., Disappearance of plasmaspheric hiss following interplanetary shock, Geophys. Res. Lett., 42, 3129-3140, 2015.

346.	Dai, L., Wang, C., Duan, S. P., He, Z. H., Wygant, J. R., Cattell, C. A., Tao, X., Su, Z. P., Kletzing C. A., Baker, D. N., Li, X. L., Malaspina, D., Blake, J. B., Fennell, J., Claudepierre, S., Turner, D. L. Reeves, G. D. Funsten, H. O., Spence, H. E., Angelopoulos V. Fruehauff D., Chen L. J., Thaller, S., Breneman, A., and Tang X. W., Near-Earth injection of MeV electrons associated with intense dipolarization electric fields: Van Allen Probes observations, Geophys. Res. Lett., 42, 6170-6179, 2015.

345.	Hui Zhu, Zhenpeng Su, Fuliang Xiao, Huinan Zheng, Yuming Wang, Chao Shen, Tao Xian, Shui Wang, C. A. Kletzing, W. S. Kurth, G. B. Hospodarsky, H. E. Spence, G. D. Reeves, H. O. Funsten, J. B. Blake, and D. N. Baker, Plasmatrough exohiss waves observed by Van Allen Probes: Evidence for leakage from plasmasphere and resonant scattering of radiation belt electrons, Geophys. Res. Lett., , 2015.

344.	Zhenpeng Su, Hui Zhu, Fuliang Xiao, Huinan Zheng, Yuming Wang, Chao Shen, Min Zhang, Shui Wang, C. A. Kletzing, W. S. Kurth, G. B. Hospodarsky, H. E. Spence, G. D. Reeves, H. O. Funsten, J. B. Blake, and D. N. Baker, Disappearance of plasmaspheric hiss following interplanetary shock, Geophys. Res. Lett., , 2015.

343.	Y Wang, Z Zhou, C Shen, R Liu, and S Wang, , J. Geophys. Res. - Space Phys., 120 (3), 1543-1565, 2015.

342.	Huang, C., M. Y. Wu, Quanming Lu, R. S. Wang, and S. Wang, Electron acceleration in the dipolarization front driven by magnetic reconnection, J. Geophys. Res. - Space Phys., 120, 1759-1765, 2015.

341.	Gao, X. L., W. Li, J. Bortnik, R. M. Thorne, Quanming Lu, Q. L. Ma, X. Tao, and S. Wang, The effect of different solar wind parameters upon significant relativistic electron flux dropouts in the magnetosphere, J. Geophys. Res. - Space Phys., 120, 4324-4337, 2015.

340.	Lu,S., Quanming Lu, Y. Lin, X. Y. Wang,, Y. S. Ge, R. S. Wang, M. Zhou, H. S. Fu, C. Huang, M. Y. Wu, and S. Wang, Dipolarization fronts as earthward propagating flux ropes: A three-dimensional global hybrid simulation, J. Geophys. Res. - Space Phys., 120, 6286-6300, 2015.

339.	Wu, M. Y., C. Huang, Quanming Lu, M. Volwerk, R. Nakamura, Z. Voros, T. L.Zhang, and S. Wang, In situ observations of multistage electron acceleration in magnetic reconnection, J. Geophys. Res. - Space Phys., 120, 6320-6331, 2015.

338.	Wang, G. Q., Y. S. Ge, T. L. Zhang, R. Nakamura, M. Volwerk, W. Baumjohann, A. M. Du, and Quanming Lu, A statistical analysis of Pi2-band waves in the plasma sheet and their relation to magnetospheric drivers, J. Geophys. Res. - Space Phys., 120, 6167-6175, 2015.

337.	Wang, Yuming, Zhenjun Zhou, Chenglong Shen, Rui Liu, and S. Wan, Investigating plasma motion of magnetic clouds at 1 AU through a velocity-modified cylindrical force-free flux rope model, J. Geophys. Res. - Space Phys., 120, 1543 - 1563, 2015.

336.	Wang, Yuming, Zhenjun Zhou, Chenglong Shen, Rui Liu, and S. Wang, Investigating plasma motion of magnetic clouds at 1 AU through a velocity-modified cylindrical force-free flux rope model,, J. Geophys. Res. - Space Phys., 120, 1543, 2015.

335.	Wang, Yuming, Zhenjun Zhou, Chenglong Shen, Rui Liu, and S. Wang, Investigating plasma motion of magnetic clouds at 1 AU through a velocity-modified cylindrical force-free flux rope model, J. Geophys. Res. - Space Phys., 120, 1543-1565, 2015.

334.	Xiao, F. L., Yang, C., Su, Z. P., Zhou, Q. H., He, Z. G., He, Y. H., Baker, D. N., Spence, H. E., Funsten, H. O., and Blake, J. B., Wave-driven butterfly distribution of Van Allen belt relativistic electrons, Nat. Comm., 6, 8590, 2015.

333.	Su, Z. P., Zhu, H., Xiao, F. L., Zong, Q.-G., Zhou, X.-Z., Zheng, H. N., Wang, Y. M., Wang, S., Hao, Y.-X., Gao, Z. L., He, Z. G., Baker, D. N., Spence, H. E., Reeves, G. D., Blake, J. B., and Wygant, J. R., Ultra-low-frequency wave-driven diffusion of radiation belt relativistic electrons, Nat. Comm., 6, 10096, 2015.

332.	Su, Zhenpeng, Hui Zhu, Fuliang Xiao, Qiugang Zong, Xuzhi Zhou, Huinan Zheng, Yuming Wang, S. Wang, Y.-X. Hao, Zhonglei Gao, Zhaoguo He, Daniel Baker, Harlan Spence, Geoffrey Reeves, J Blake, and John Wygant, Ultra low frequency wave-driven diffusion of radiation belt relativistic electrons, Nat. Comm., 6, 10096, 2015.

331.	Shan, L. C., Quanming Lu,, Christian Mazelle, C. Huang, T.L. Zhang, M. Y. Wu, X. L. Gao, and S. Wang, The shape of the Venusian bow shock at solar minimum and maximum: Revisit based on VEX observations, Planet. & Space Sci., 109-110, 32-37, 2015.

330.	Hui Zhu, Observations and simulations on wave-particle interactions in the inner magnetosphere, Ph.D Dissertation, , 2015.

329.	Wu, C. S.; Yoon, P. H.; Wang, C. B., A theory of heating of quiet solar corona, Phys. Plasmas, 22, 032901, 2015.

328.	Guo, Z. F., M. H. Hong,, Y. Lin, A. M. Du, X. Y. Wang, M. Y. Wu, and Quanming Lu, Generation of kinetic Alfven waves in the high-latitude near-Earth magnetotail: A global hybrid simulation, Phys. Plasmas, 22, 022117, 2015.

327.	Lu,S., Y. Lin, Quanming Lu, X. Y. Wang, R. S. Wang, C. Huang, M. Y. Wu, and S. Wang, Evolution of flux ropes in the magnetotail: A three-dimensional global hybrid simulation, Phys. Plasmas, 22, 052901, 2015.

326.	Zhou, F. S., C. Huang, Quanming Lu, J. L. Xie, and S. Wang, The evolution of the ion diffusion region during collisionless magnetic reconnection in a force-free current sheet, Phys. Plasmas, 22, 092110, 2015.

325.	Tingyu Gou, Rui Liu, and Yuming Wang, Do All Candle-Flame-Shaped Flares Have the Same Temperature Distribution?, Sol. Phys., 290*, 2211-2230, 2015.

324.	Gou, Tingyu, Rui, Liu, and Yuming Wang, Do All Candle-Flame-Shaped Flares Have the Same Temperature Distribution?, Sol. Phys., 290*, 2211-2230, 2015.
Abstract. We performed a differential emission measure (DEM) analysis of candle-flameshaped flares observed with the Atmospheric Imaging Assembly onboard the Solar Dynamic Observatory. The DEM profile of flaring plasmas generally exhibits a double peak distribution in temperature, with a cold component around log T ≈ 6.2 and a hot component around log T ≈ 7.0. Attributing the cold component mainly to the coronal background, we propose a mean temperature weighted by the hot DEM component as a better representation of flaring plasma than the conventionally defined mean temperature, which is weighted by the whole DEM profile. Based on this corrected mean temperature, the majority of the flares studied, including a confined flare with a double candle-flame shape sharing the same cusp-shaped structure, resemble the famous Tsuneta flare in temperature distribution, i.e., the cusp-shaped structure has systematically higher temperatures than the rounded flare arcade underneath. However, the M7.7 flare on 19 July 2012 poses very intriguing violation of this paradigm: the temperature decreases with altitude from the tip of the cusp toward the top of the arcade; the hottest region is slightly above the X-ray loop-top source that is co-spatial with the emission-measure-enhanced region at the top of the arcade. This signifies that a different heating mechanism from the slow-mode shocks attached to the reconnection site operates in the cusp region during the flare decay phase. We are grateful to the SDO team for the free access to the data and the development of the data analysis software. R. Liu acknowledges the Thousand Young Talents Program of China, NSFC 41222031 and 41474151, and NSF AGS-1153226. This work was also supported by NSFC 41131065 and 41121003, 973 key project 2011CB811403, CAS Key Research Program KZZD-EW-01-4, the fundamental research funds for the central universities WK2080000031.

323.	张卫, 史钰峰, 单旭, 李毅人, 郝新军, 缪彬, 徐春凯, 陈向军, 陆全明, 汪毓明, and 张铁龙, 空间低能离子探测器的紫外响应测试 (in Chinese), 原子核物理评论, 32, 358-362, 2015.

2014 Top

322.	Wang, R. S, R. Nakamura, T. Zhang, A. Du, W. Baumjohann, Quanming Lu, and A. N. Fazakerley, Evidence of transient reconnection in the outflow jet of primary reconnection site, Ann. Geophys., 32, 1-10, 2014.

321.	Lu, S, Quanming Lu, C. Huang, Q. L. Dong, J. Q. Zhu, Z. M. Sheng, S. Wang, and J. Zhang, Formation of super-Alfvénic electron jets during laser-driven magnetic reconnection at the Shenguang-II facility: particle-in-cell simulations, New J. Phys., 16, 083021, 2014.

320.	Sun, J. C., X. L. Gao, Quanming Lu, and S. Wang, The efficiency of ion stochastic heating by a monochromatic obliquely propagating low-frequency Alfven wave, Plasma Sci. & Tech., 16, 919-923, 2014.

319.	Xiao, F. L., Zong, Q. G., Wang, Y. F., He, Z. G., Su, Z, P., Yang, C., and Zhou, Q. H., Generation of proton aurora by magnetosonic waves, Sci. Rep., 4, 5190, 2014.

318.	Rui Liu,, Yuming Wang, and Chenglong Shen, Early Evolution of An Energetic Coronal Mass Ejection And Its Relation to EUV Waves, Astrophys. J., 797, 37, 2014.

317.	Rui Liu, Yuming Wang, and Chenglong Shen, Early Evolution of An Energetic Coronal Mass Ejection And Its Relation to EUV Waves, Astrophys. J., 797, 37, 2014. (doi:10.1088/0004-637X/797/1/37)

316.	Liu, Rui, Yuming Wang, and Chenglong Shen, Early Evolution of An Energetic Coronal Mass Ejection And Its Relation to EUV Waves, Astrophys. J., 797, 37(15pp), 2014.

315.	Bernhard Kliem, Tibor Torok, Viacheslav S. Titov, Roberto Lionello, Jon A. Linker, Rui Liu, Chang Liu, and Haimin Wang, Slow Rise and Partial Eruption of a Double-Decker Filament. II A Double Flux Rope Model, Astrophys. J., 792, article id. 107, 2014. (DOI: 10.1088/0004-637X/792/2/107)

314.	Rui Liu, Viacheslav S. Titov, Tingyu Gou, Yuming Wang, Kai Liu, and Haimin Wang, An Unorthodox X-Class Long-Duration Confined Flare, Astrophys. J., 790, article id. 8, 2014. (doi:10.1088/0004-637X/790/1/8)

313.	Rui Liu, Viacheslav Titov, Tingyu Gou, Yuming Wang, Kai Liu, and Haimin Wang, An Unorthodox X-Class Long-Duration Confined Flare, Astrophys. J., 790, 8(12pp), 2014.

312.	Q Zhang, R Liu, Y Wang, C Shen, K Liu, J Liu, and S Wang, A Prominence Eruption Driven by Flux Feeding from Chromospheric Fibrils, Astrophys. J., 789(2), 133, 2014.

311.	Quanhao Zhang, Rui Liu, Yuming Wang, Chenglong Shen, Kai Liu, Jiajia Liu, and S. Wang, A Prominence Eruption Driven by Flux Feeding from Chromospheric Fibrils, Astrophys. J., 789*, article id. 13, 2014. (doi:10.1088/0004-637X/789/2/133)

310.	Zhang, Qanhao, Rui Liu, Yuming Wang, Chenglong Shen, Kai Liu, Jiajia Liu, and Shui Wang, A prominence eruption driven by flux feeding from chromospheric fibrils, Astrophys. J., 789*, 133(9pp), 2014.

309.	Cheng, X., M. D. Ding, J. Zhang, X. D. Sun, Y. Guo, Y. M. Wang, B. Kliem, and Y. Y. Deng, Formation of a Double-Decker Magnetic Flux Rope in the Sigmoidal Solar Active Region 11520, Astrophys. J., 789, 93(12pp), 2014.

308.	HongQiang Song, Jie Zhang, Xin Cheng, Yao Chen, Rui Liu, Yuming Wang, and Bo Li, Temperature Evolution of a Magnetic Flux Rope in a Failed Solar Eruption, Astrophys. J., 784, article id. 48, 2014.

307.	H. Q. Song, J. Zhang, X. Cheng, Y. Chen, R. Liu, Y. M. Wang, and B. Li, Temperature evolution of a magnetic flux rope in a failed solar eruption, Astrophys. J., 784, 48(6pp), 2014.

306.	J Liu, Y Wang, R Liu, Q Zhang, K Liu, C Shen, and S Wang, When and how does a prominence-like jet gain kinetic energy?, Astrophys. J., 782, 94, 2014.

305.	Jiajia Liu, Yuming Wang, Rui Liu, Quanhao Zhang, Kai Liu, Chenglong Shen, and S. Wang, When and how does a Prominence-like Jet Gain Kinetic Energy?, Astrophys. J., 782, article id. 94, 2014.

304.	Jiajia Liu, Yuming Wang, Rui Liu, Quanhao Zhang, Kai Liu, Chenglong Shen, and S. Wang, When and how does a prominence-like jet gain kinetic energy?, Astrophys. J., 782*, 94, 2014.

303.	Gao, X. L., Quanming Lu, X. Li, Y. F Hao, X. Tao, and S. Wang, Ion dynamics during the parametric instabilities of a left-hand polarized Alfven wave in a proton-electron-alpha plasma, Astrophys. J., 780, 56, 2014.

302.	Liu-Guan Ding, Gang Li, Yong Jiang, Gui-Ming Le, Cheng-Long Shen, Yu-Ming Wang, Yao Chen, Fei Xu, Bin Gu, and Ya-Nan Zhang, INTERACTION BETWEEN TWO CORONAL MASS EJECTIONS IN THE 2013 MAY 22 LARGE, Astrophys. J. Lett., 793, L35, 2014.

301.	Ding, Liuguan, Gang Li, Jiang Yong, Guiming Le, Chenglong Shen, Yuming Wang, Yao Chen, Fei Xu, Bin Gu, and Yanan Zhang, Interaction between two coronal mass ejections in the 2013 May 22 large solar energetic particle event, Astrophys. J. Lett., 793*, L35(7pp), 2014.

300.	Wu, M. Y., Quanming Lu, C. Huang, P. R. Wang, R. S. Wang, and S. Wang, Dissipation of an electron phase-space hole and its consequence on electron heating, Astrophys. & Space Sci., 352, 565-570, 2014.

299.	Yushu Zhang, Hui Zhu, Lewei Zhang, Yihua He, Zhonglei Gao, Qinghua Zhou, Chang Yang, and Fuliang Xiao, Effect of low energy electron injection on storm-time evolution of radiation belt energetic electrons: three-dimensional modeling, Astrophys. & Space Sci., 352, 613-620, 2014.

298.	Zhonglei Gao, Hui Zhu, Lewei Zhang, Qinghua Zhou, Chang Yang, and Fuliang Xiao, Test Particle Simulations of Interaction Between Monochromatic Chorus Waves and Radiation Belt Relativistic Electrons, Astrophys. & Space Sci., , 2014.

297.	He Zhaoguo, Hui Zhu, Siqing Liu, Qiugang Zong, Yongfu Wang, Ruilin Lin, Liqin Shi, and Jiancun Gong, Correlated observations and simulations on the buildup of radiation belt electron fluxes driven by substorm injections and chorus waves, Astrophys. & Space Sci., , 2014.

296.	Liangwen Shi, Chenglong Shen, and Yuming Wang, The internplanetary origins of geomagnetic storm with Dstmin<=-50nT in 2007 - 2012 (in chinese), Chinese J. Geophys., 57 (11）*, 3822-3833, 2014.

295.	Gao, X. L., W. Li, R. M. Thorne, J. Bortnik, V.Angelopoulos, Quanming Lu, X. Tao, and S. Wang, New evidence for generation mechanisms of discrete and hiss-like whistler mode waves, Geophys. Res. Lett., 41, 4805-4801, 2014.

294.	Wang, R. S., Quanming Lu, Y. V. Khotyaintsev, M. Volwerk, A. M.Du, R. Nakamura, W. D. Gonzalez, X. Sun, W. Baumjohann, X. Li, T. L. Zhang, A. N. Fazakerley, C. Huang, and M. Y. Wu, Observation of double layer in the separatrix region during magnetic reconnection, Geophys. Res. Lett., 41, 4851-4858, 2014.

293.	Tao, X, Quanming Lu, S. Wang, and L. Dai, Effects of magnetic field configuration on the day-night asymmetry of chorus occurrence rate: A numerical study, Geophys. Res. Lett., 41, 6577-6582, 2014.

292.	Su, Z. P., Xiao, F. L., Zheng, H. N., He, Z. G., Zhu, H., Zhang, M., Shen, C., Wang, Y. M., Wang, S., Kletzing, C. A., Kurth, W. S., Hospodarsky, G. B., Spence, H. E., Reeves, G. D., Funsten, H. O., Blake, J. B., and Baker, D. N., Nonstorm-time dynamics of electron radiation belts observed by the Van Allen Probes, Geophys. Res. Lett., 41, 229-235, 2014.

291.	Zhenpeng Su, Fuliang Xiao, Huinan Zheng, Zhaoguo He, Hui Zhu, Min Zhang, C Shen, Yuming Wang, S. Wang, Craig Kletzing, William Kurth, George Hospodarsky, Harlan Spence, Geoffrey Reeves, Herbert Funsten, J. Blake, Daniel Baker, and John Wygant, Nonstorm-time dynamics of electron radiation belts observed by the Van Allen Probes, Geophys. Res. Lett., 41, 229-235, 2014.

290.	Zhenpeng Su, Fuliang Xiao, Huinan Zheng, Zhaoguo He, Hui Zhu, Min Zhang, Chao Shen, Yuming Wang, Shui Wang, C. A. Kletzing, W. S. Kurth, G. B. Hospodarsky, H. E. Spence, G. D. Reeves, H. O. Funsten, J. B. Blake, and D. N. Baker, Nonstorm time dynamics of electron radiation belts observed by the Van Allen Probes, Geophys. Res. Lett., , 2014.

289.	Yuming Wang, Boyi Wang, Chenglong Shen, Fang Shen, and Noe Lugaz, Deflected propagation of a coronal mass ejection from the corona to interplanetary space, J. Geophys. Res. - Space Phys., 119(7), 5117 - 5132, 2014.

288.	Chenglong Shen, Yuming Wang, Zonghao Pan, Bin Miao, Pinzhong Ye, and S. Wang, Full Halo Coronal Mass Ejections: Arrival at the Earth, J. Geophys. Res. - Space Phys., 119(7), 5107 - 5116, 2014.

287.	Zhenpeng Su, Hui Zhu, Fuliang Xiao, Huinan Zheng, Yuming Wang, Zhaoguo He, Chao Shen, Chenglong Shen, CB Wang, Rui Liu, Min Zhang, Shui Wang, CA Kletzing, WS Kurth, GB Hospodarsky, Harlan E Spence, GD Reeves, HO Funsten, JB Blake, DN Baker, and JR Wygant, Intense duskside lower band chorus waves observed by Van Allen Probes: Generation and potential acceleration effect on radiation belt electrons, J. Geophys. Res. - Space Phys., 119(6), 4266-4273, 2014.

286.	Su, Zhenpeng, Hui Zhu, Fuliang Xiao, Huinan Zheng, Yuming Wang, Q.-G. Zong, Zhaoguo He, Chao Shen, Min Zhang, Shui Wang, C. A. Kletzing, W. S. Kurth, G. B. Hospodarsky, H. E. Spence, G. D. Reeves, H. O. Funsten, J. B. Blake, and D. N. Baker, Quantifying the relative contributions of substorm injections and chorus waves to the rapid outward extension of electron radiation belt, J. Geophys. Res. - Space Phys., 119(12), 10023-10040, 2014.

285.	Fang Shen, Chenglong Shen, Jie Zhang, Phillip Hess, Yuming Wang, Xueshang Feng, Hongze Cheng, and Yi Yang, Evolution of the 2012 July 12 CME from the Sun to the Earth: Data-Constrained Three-Dimensional MHD Simulations, J. Geophys. Res. - Space Phys., 119 (9), 7128-7141, 2014.

284.	Shan, L. C., Quanming Lu, M. Y. Wu, X. L. Gao, C. Huang, T. L. Zhang, and S. Wang, Transmission of large amplitude ULF waves through a quasi-parallel shock at Venus, J. Geophys. Res. - Space Phys., 119, 237-245, 2014.

283.	Huang, C., Quanming Lu, S. Lu, P. R. Wang, and S. Wang, The effect of a guide field on the structures of magnetic islands formed during multiple X line reconnection: two-dimensional particle-in-cell simulations, J. Geophys. Res. - Space Phys., 119, 798-807, 2014.

282.	Hao, Y. F., Quanming Lu, X. L. Gao, C. Huang, S. Lu, L. C. Shan, and S. Wang, He2+ dynamics and ion cyclotron waves in the downstream of quasi-perpendicular shocks: 2D hybrid simulations, J. Geophys. Res. - Space Phys., 119, 3225-3226, 2014.

281.	Lin, Y., X. Y. Wang, S. Lu, J. D. Perez, and Quanming Lu, Investigation of Storm-Time Magnetotail and Ion Injection Using Three-Dimensional Global Hybrid Simulation, J. Geophys. Res. - Space Phys., 119, 7413-7432, 2014.

280.	Huang,C., Quanming Lu, P. R. Wang, M. Y. Wu, and S. Wang, Characteristics of electron holes generated in the separatrix region during anti-parallel magnetic reconnection, J. Geophys. Res. - Space Phys., 119, 6445-6454, 2014.

279.	Gao, X. L., W. Li, R. M. Thorne, J. Bortnik, V. Angelopoulos, Quanming Lu, X. Tao, and S. Wang, Statistical results describing the bandwidth and coherence coefficient of whistler mode waves using THEMIS waveform data, J. Geophys. Res. - Space Phys., 119, 8992-9003, 2014.

278.	Wang, R. S., Quanming Lu, A. M. Du, R.Nakamura, S. Lu, C. Huang, C. X. Liu, and M. Y. Wu, In situ observation of magnetic reconnection in the front of bursty bulk flow, J. Geophys. Res. - Space Phys., 119, 9952-9961, 2014.

277.	Xiao, F. L., Yang, C., He, Z. G., Su, Z. P., Zhou, Q. H., He, Y. H., Kletzing, C. A., Kurth, W. S., Hospodarsky, G. B., Spence, H. E., Reeves, G. D., Funsten, H. O., Blake, J. B., and Baker, D. N., Wave acceleration of radiation belt relativistic electrons during March 2013 geomagnetic storm, J. Geophys. Res. - Space Phys., 119, 3325-3332, 2014.

276.	Su, Z. P., Zhu, H., Xiao, F. L., Zheng, H. N., Wang, Y. M., He, Z. G., Shen, C., Shen, C. L., Wang, C. B., Liu, R., Zhang, M., Wang, S., Kletzing, C. A., Kurth, W. S., Hospodarsky, G. B., Spence, H. E., Reeves, G. D. Funsten, H. O., Blake, J. B., and Baker, D. N., Intense duskside lower-band chorus waves observed by Van Allen Probes: Generation and potential acceleration effect on radiation belt electrons, J. Geophys. Res. - Space Phys., 119, 4266-4273, 2014.

275.	Su, Z. P., Zhu, H., Xiao, F. L., Zheng, H. N., Wang, Y. M., Zong, Q.-G., He, Z. G., Shen, C., Zhang, M., Wang, S., Kletzing, C. A., Kurth, W. S., Hospodarsky, G. B., Spence, H. E., Reeves, G. D. Funsten, H. O., Blake, J. B., and Baker, D. N., Quantifying the relative contributions of substorm injections and chorus waves to the rapid outward extension of electron radiation belt, J. Geophys. Res. - Space Phys., 119, 10023-10040, 2014.

274.	Zhenpeng Su, Hui Zhu, Fuliang Xiao, Huinan Zheng, Zhaoguo He, Min Zhang, Chao Shen, Yuming Wang, Shui Wang, C. A. Kletzing, W. S. Kurth, G. B. Hospodarsky, H. E. Spence, G. D. Reeves, H. O. Funsten, J. B. Blake, and D. N. Baker, Intense duskside lower band chorus waves observed by Van Allen Probes: Generation and potential acceleration effect on radiation belt electrons, J. Geophys. Res. - Space Phys., 119, 4266-4233, 2014.

273.	Zhenpeng Su, Hui Zhu, Fuliang Xiao, Huinan Zheng, Yuming Wang, Zhaoguo He, Chao Shen, Chenglong Shen, Chuanbing Wang, Rui Liu, Bin Miao, Min Zhang, Shui Wang, Craig Kletzing, William Kurth, George Hospodarsky, Harlan Spence, Geoffrey Reeves, Herbert Funsten, J. Blake, Daniel Baker, and John Wygant, Intense duskside lower-band chorus waves observed by Van Allen Probes: Generation and potential acceleration effect on radiation belt electrons, J. Geophys. Res. - Space Phys., 119, 4266-4273, 2014.

272.	Yuming Wang, Boyi Wang, Chenglong Shen, Fang Shen, and Noe Lugaz, Deflected propagation of a coronal mass ejection from the corona to interplanetary space, J. Geophys. Res. - Space Phys., 119, 5117-5132, 2014.

271.	Zhenpeng Su, Hui Zhu, Fuliang Xiao, Huinan Zheng, Yuming Wang, Zhaoguo He, Chao Shen, Chenglong Shen, Chuanbing Wang, Rui Liu, Bin Miao, Min Zhang, Shui Wang, Craig Kletzing, William Kurth, George Hospodarsky, Harlan Spence, Geoffrey Reeves, Herbert Funsten, J. Blake, Daniel Baker, and John Wygant, Intense duskside lower-band chorus waves observed by Van Allen Probes: Generation and potential acceleration effect on radiation belt electrons, J. Geophys. Res. - Space Phys., 119, 4266-4273, 2014.

270.	Shen, Chenglong, Yuming Wang, Zonghao Pan, Bin Miao, Pinzhong Ye, and S. Wang, Full Halo Coronal Mass Ejections: Arrival at the Earth, J. Geophys. Res. - Space Phys., 119, 5107-5116, 2014.

269.	Shen, Fang, Chenglong Shen, Jie Zhang, Phillip Hess, Yuming Wang, Xueshang Feng, Hongze Cheng, and Yi Yang, Evolution of the 12 July 2012 CME from the Sun to the Earth: Data-constrained three-dimensional MHD simulations, J. Geophys. Res. - Space Phys., 119, 7128-7141, 2014.

268.	Dmitriev, A. V., Suvorova, A. V., Chao, J. K., Wang, C. B., Rastaetter, L., Panasyuk, M. I. & Myagkova, I. N., Anomalous dynamics of the extremely compressed magnetosphere during 21 January 2005 magnetic storm, J. Geophys. Res. - Space Phys., 10.1002/2013JA019534, 2014.

267.	Su, ZP et al., Intense duskside lower band chorus waves observed by Van Allen Probes: Generation and potential acceleration effect on radiation belt electrons, J. Geophys. Res. - Space Phys., , 2014.

266.	Wang, Yuming, Multiple magnetic clouds in interplanetary space: A review and perspective (in Chinese), J. Univ. of Sci. & Tech. of China, 44(5), 100-105, 2014.

265.	Wu, C. S.; Yoon, P. H.; Wang, C. B., Ion temperature in plasmas with intrinsic Alfven waves, Phys. Plasmas, 21, 104507, 2014.

264.	Tao, X., and Quanming Lu, Formation of electron kappa distributions due to interactions with parallel propagating whistler waves, Phys. Plasmas, 21, 022901, 2014.

263.	Su, Z. P., Zhu, H., Xiao, F. L., Zheng, H. N., Zhang, M., Liu, Y., Shen, C., Wang, Y. M., and Wang, S., Latitudinal dependence of nonlinear interaction between electromagnetic ion cyclotron wave and terrestrial ring current ions, Phys. Plasmas, 21, 052310, 2014.

262.	Zhenpeng Su, Hui Zhu, Fuliang Xiao, Huinan Zheng, Min Zhang, Y. C.-M. Liu, Chao Shen, Yuming Wang, and Shui Wang, Latitudinal dependence of nonlinear interaction between electromagnetic ion cyclotron wave and terrestrial ring current ions, Phys. Plasmas, 21, 052310, 2014.

261.	Zhenpeng Su, Hui Zhu, Fuliang Xiao, Huinan Zheng, Min Zhang, Yong Liu, Chao Shen, Yuming Wang, and Shui Wang, Latitudinal dependence of nonlinear interaction between electromagnetic ion cyclotron wave and terrestrial ring current ions, Phys. Plasmas, 21, doi:10.1063/1.4880036, 2014.

260.	Wang, C. B.; Wang, Bin; Lee, L. C., Compound Effect of Alfven Waves and Ion-Cyclotron Waves on Heating/Acceleration of Minor Ions via the Pickup Process, Sol. Phys., 289, 2014.

259.	Zhang, S. H., A. M. Du, X. S. Feng, X. Cao, Quanming Lu, Y. P. Yang, G. X Chen, and Y. Zhang, Electron Acceleration in a Dynamically Evolved Current Sheet Under Solar Coronal Conditions, Sol. Phys., 289, 1607-1623, 2014.

2013 Top

258.	Shan, L. C., Quanming Lu, T. L. Zhang, X. L. Gao, C. Huang, Y. Q. Su, and S. Wang, Comparison between magnetic coplanarity and MVA methods in determining the normal of Venusian bow shock, Chinese Science Bulletin, 58, 2013.

257.	Quanming Lu, S. Lu, C. Huang, M. Y. Wu, and S. Wang, Self-reinforcing process of the reconnection electric field in the electron diffusion region and onset of collisionless magnetic reconnection, Plasma Phys. Control. Fusion, 55, 085019, 2013.

256.	M. Y. Wu, Quanming Lu, J. Zhu, P. R. Wang, and S. Wang, Electromagnetic particle-in-cell simulations of electron holes formed during the electron two-stream instabilty, Plasma Science and Technology, 15, 17, 2013.

255.	Zong, Q.-G., Yuan, C. J., Wang, Y. F., and Su, Z. P., Dynamic variation and the fast acceleration of particles in Earth's radiation belt, Sci. China-Earth Sci., 56, 1118-1140, 2013.

254.	Xiao, F. L., Zong, Q. G., Su, Z. P., Yang, C., He, Z. G., Wang, Y. Fu., and Gao, Z. L., Determining the mechanism of cusp proton aurora, Sci. Rep., 3, 1654, 2013.

253.	Yuming Wang, Zhenjun Zhou, Jiajia Liu, Chenglong Shen, and Shui Wang, Dynamic processes of coronal mass ejections in interplanetary space (Chinese Version), Science China：Earth Sciences, 43, 6：934-950, 2013.

252.	Yuming Wang, Zhenjun Zhou, Jiajia Liu, Chenglong Shen, and Shui Wang, Dynamic process of coronal mass ejections in interplanetary space (in Chinese), Science in China, 43(6), 934-950, 2013.

251.	Rui Liu, Chang Liu, Yan Xu, Wei Liu, Bernhard Kliem, and Haimin Wang, Observation of A Moreton Wave and Wave-Filament Interactions Associated with the Renowned X9 Flare on 1990 May 24, Astrophys. J., 773, 166, 2013. (doi:10.1088/0004-637X/773/2/166)

250.	Kai Liu, Jie Zhang, Yuming Wang, and Xin Cheng, ON THE ORIGIN OF THE EXTREME-ULTRAVIOLET LATE PHASE OF SOLAR FLARES, Astrophys. J., 768, 150(13pp), 2013.
Abstract. Solar flares typically have an impulsive phase that is followed by a gradual phase as best seen in soft X-ray emissions. A recent discovery based on the EUV Variability Experiment observations on board the Solar Dynamics Observatory (SDO) reveals that some flares exhibit a second large peak separated from the first main phase peak by tens of minutes to hours, which is coined as the flare’s EUV late phase. In this paper, we address the origin of the EUV late phase by analyzing in detail two late phase flares, an M2.9 flare on 2010 October 16 and an M1.4 flare on 2011 February 18, using multi-passband imaging observations from the Atmospheric Imaging Assembly on board SDO. We find that (1) the late phase emission originates from a different magnetic loop system, which is much larger and higher than the main phase loop system. (2) The two loop systems have different thermal evolution. While the late phase loop arcade reaches its peak brightness progressively at a later time spanning for more than one hour from high to low temperatures, the main phase loop arcade reaches its peak brightness at almost the same time (within several minutes) in all temperatures. (3) Nevertheless, the two loop systems seem to be connected magnetically, forming an asymmetric magnetic quadruple configuration. (4) Further, the footpoint brightenings in UV wavelengths show a systematic delay of about one minute from the main flare region to the remote footpoint of the late phase arcade system. We argue that the EUV late phase is the result of a long-lasting cooling process in the larger magnetic arcade system. SDO is a mission of NASA’s Living With a Star Program. K.L. and Y.W. are supported by 973 key project 2011CB811403 and NSFC 41131065. K.L. is also supported by the scholarship granted by the China Scholarship Council (CSC) under file No. 2011634065. J.Z. is supported by NSF grant ATM-0748003, AGS-1156120, and NASA grant NNG05GG19G.

249.	Gao, X. L., Quanming Lu, X. Li, L. C. Shan, and S. Wang, Electromagnetic proton/proton instability and its implications for ion heating in the extended fast solar wind, Astrophys. J., 764, 71, 2013.

248.	C. Shen, G. Li, X. Kong, J. Hu, X. D. Sun, L. Ding, Y. Chen, and Yuming Wang, Compound twin coronal mass ejections in the 17 May 2012 GLE event, Astrophys. J., 763, 114, 2013.

247.	Yuming Wang, Lijuan Liu, Chenglong Shen, Rui Liu, and S. Wang, Waiting Times of Quasi-homologous Coronal Mass Ejections from Super Active Regions, Astrophys. J., 763, L43, 2013.

246.	C. Shen, G. Li, X. Kong, J. Hu, X. D. Sun, L. Ding, Y. Chen, Yuming Wang, and L. Xia, Compound twin coronal mass ejections in the 2012 May 17 GLE event, Astrophys. J., 763, 114, doi:10.1088/0004-637X/763/2/114, 2013.
Abstract. We report a multiple spacecraft observation of the 2012 May 17 GLE event. Using the coronagraph observations by SOHO/LASCO, STEREO-A/COR1, and STEREO-B/COR1, we identify two eruptions resulting in two coronal mass ejections (CMEs) that occurred in the same active region and close in time (∼2 minutes) in the 2012 May 17 GLE event. Both CMEs were fast. Complicated radio emissions, with multiple type II episodes, were observed from ground-based stations: Learmonth and BIRS, as well as theWAVES instrument on board the Wind spacecraft. High time-resolution SDO/AIA imaging data and SDO/HMI vector magnetic field data were also examined. Acomplicated pre-eruption magnetic field configuration, consisting of twisted flux-tube structure, is reconstructed. Solar energetic particles (SEPs) up to several hundred MeV nucleon−1 were detected in this event. Although the eruption source region was near the west limb, the event led to ground-level enhancement. The existence of two fast CMEs and the observation of high-energy particles with ground-level enhancement agrees well with a recently proposed “twin CME” scenario. We are grateful to the STEREO/SECCHI, SOHO/LASCO, and Learmonth teams for making their data available online. The SDO data are courtesy of NASA and the HMI and AIA science teams, and the magnetic field extrapolation code is provided by Dr. Wiegelmann. We thank Dr. Stephen White and Dr. Bill Erickson for providing the BIRS data. This work is supported at UAH by NSF grants ATM-0847719, AGS-0962658 and AGS- 1135432; NASA grants NNX11AO64G and NNX09AP74A; at SDWHby NNSFC grants 41028004, 40825014, and 40890162; at USTC by 973 key project 2011CB811403, NSFC 41131065, 40904046, 40874075, and 41121003 and the CASKey Research Program KZZD-EW-01-4. X.D.S. is supported by NASA contract NAS5-02139 (HMI) to Stanford University.

245.	Quanming Lu, L. C. Shan, T.L Zhang, G. P. Zank, Z. W. Yang, M. Y. Wu, A. M. Du, and S. Wang, The role of pickup ions on the structure of the Venusian bow shock and its implications for the termination shock, Astrophys. J. Lett., 773, L24, 2013.

244.	Yuming Wang,, Lijuan Liu,, and Chenglong Shen, Rui Liu, Pinzhong Ye, and S. Wang, WAITING TIMES OF QUASI-HOMOLOGOUS CORONAL MASS EJECTIONS FROM SUPER ACTIVE REGIONS, Astrophys. J. Lett., 763, L43, 2013.

243.	Yuming Wang, Lijuan Liu, Chenglong Shen, Rui Liu, Pinzhong Ye, and S. Wang, Waiting Times of Quasi-homologous Coronal Mass Ejections from Super Active Regions, Astrophys. J. Lett., 763, L43, 2013. (http://adsabs.harvard.edu/abs/2013ApJ...763L..43W)

242.	Yuming Wang, Lijuan Liu, Chenglong Shen, Rui Liu, Pinzhong Ye, and S. Wang, Waiting Times of Quasi-homologous Coronal Mass Ejections from Super Active Regions, Astrophys. J. Lett., 763, L43, doi:10.1088/2041-8205/763/2/L43, 2013.
Abstract. Why and how do some active regions (ARs) frequently produce coronal mass ejections (CMEs)? These are key questions for deepening our understanding of the mechanisms and processes of energy accumulation and sudden release in ARs and for improving our space weather prediction capability. Although some case studies have been performed, these questions are still far from fully answered. These issues are now being addressed statistically through an investigation of the waiting times of quasi-homologous CMEs from super ARs in solar cycle 23. It is found that the waiting times of quasi-homologous CMEs have a two-component distribution with a separation at about 18 hr. The first component is a Gaussian-like distribution with a peak at about 7 hr, which indicates a tight physical connection between these quasi-homologous CMEs. The likelihood of two or more occurrences of CMEs faster than 1200 km s−1 from the same AR within 18 hr is about 20%. Furthermore, the correlation analysis among CME waiting times, CME speeds, and CME occurrence rates reveals that these quantities are independent of each other, suggesting that the perturbation by preceding CMEs rather than free energy input is the direct cause of quasi-homologous CMEs. The peak waiting time of 7 hr probably characterizes the timescale of the growth of the instabilities triggered by preceding CMEs. This study uncovers some clues from a statistical perspective for us to understand quasi-homologous CMEs as well as CME-rich ARs. We acknowledge the use of data from SOHO/LASCO, EIT, and MDI and the CDAW CME catalog. SOHO is a project of international cooperation between ESA and NASA. This work is supported by grants from the CAS (Key Research Program KZZD-EW-01 and 100-Talent Program), NSFC (41131065, 40904046, 40874075, and 41121003), 973 key project (2011CB811403), MOEC (20113402110001), and the fundamental research funds for the central universities. R.L. is also supported by NSF (AGS-1153226).

241.	Hao, Y. F., Quanming Lu, X. L. Gao, L. C. Shan, and S. Wang, Particle acceleration at shock waves with composite turbulence, Chinese J. Geophys., 56, 2171-2176, 2013.

240.	Liangwen Shi, Chenglong Shen, Yuming Wang, and Fang Shen, Research Progresses in Modeling the Propagation of Solar Wind Disturbances (in Chinese), Progress in Astron., 3, 267-286, 2013.

239.	Wang Chuan-Bing; Wei Jing-Dong; Wang Bin; Wang Shui, Physical Process for the Pick-Up of Minor Ions by Low-Frequency Alfven Waves, Chinese Phys. Lett., 30, 2013.

238.	Zhang, Z. C., Quanming Lu, Q. L. Dong, S. Lu, C. Huang, M. Y. Wu, Z. M. Sheng, S. Wang, and J. Zhang, Particle-in-Cell Simulations of Fast Magnetic Reconnection in Laser-Plasma Interactions, Chinese Phys. Lett., 30, 045201, 2013.

237.	Wang, P. R, C. Huang, Quanming Lu, R. S. Wang, and S. Wang, Numerical Simulations of Magnetic Reconnection in an Asymmetric Current Sheet, Chinese Phys. Lett., 30, 125202, 2013.

236.	Zhu, H., Su, Z. P., and Zheng, H. N., Counter-streaming interaction between fast magnetosonic wave and radiation belt electrons, Chinese Phys. Lett., 30, 059401, 2013.

235.	ZHU Hui, SU Zhen-Peng, and ZHENG Hui-Nan, Counter-Streaming Interaction between Fast Magnetosonic Wave and Radiation Belt Electrons, Chinese Phys. Lett., 30, 059401, 2013.

234.	Wang, R. S., A. M. Du, R. Nakamura, Quanming Lu, Y. V. Khotyaintsev, M. Volwerk, T. L. Zhang, E. A. Kronberg, P. W. Daly, and A. N. Fazakerley, Observation of multiple sub-cavities adjacent to single separatrix, Geophys. Res. Lett., 40, doi:10.1002/grl.50537, 2013.

233.	Fang Shen, Chenglong Shen, Yuming Wang, Xueshang Feng, and Changqing Xiang, Could the collision of CMEs in the heliosphere be super-elastic? --- Validation through three-dimensional simulations, Geophys. Res. Lett.*, 40, 1-5, 2013. (doi:10.1002/grl.50336)

232.	Fang Shen, Chenglong Shen, Yuming Wang, Xueshang Feng, and Changqing Xiang, Could the collision of CMEs in the heliosphere be super-elastic? --- Validation through three-dimensional simulations, Geophys. Res. Lett.*, 40, 1457-1461, doi:10.1002/grl.50336, 2013. (Cover Story, http://onlinelibrary.wiley.com/doi/10.1002/grl.v40.8/issuetoc; AGU Spotlight: Eos, 94(25),2013;)
Abstract.

231.	Qiu, Q., H. G. Yang, Quanming Lu, Q. H. Zhang, D. S. Han, and Z. J. HU, Widths of dayside auroral arcs observed at the Chinese Yellow River Station, J. Atoms. Sol.-Terres. Phys., 102, 222-227, 2013.

230.	C.Huang, Quanming Lu, M. Y. Wu, S. Lu, and S. Wang, Out-of-plane electron currents in magnetic islands formed during collisionless magnetic reconnection, J. Geophys. Res. - Space Phys., 118, 991-996, 2013.

229.	Wang, C., Z. Y. Xia, Z. Peng, and Quanming Lu, Estimating the open magnetic flux from the interplanetary and ionospheric conditions, J. Geophys. Res. - Space Phys., 118, doi;10.1002/jgra.50255, 2013.

228.	Wu, M.Y., M. Volwerk, QuanMing Lu, Z. Voros, R. Nakamura, and T. L. Zhang, The proton temperature anisotropy associated with bursty bulk flows in the magnetotail, J. Geophys. Res. - Space Phys., 118, 4875-4883, 2013.

227.	Wu, M. Y., QuanMing Lu, M. Volwerk, Z. Voros, T.L. Zhang, L. C. Shan, and C. Huang, A statistical study of electron acceleration behind the dipolarization fronts in the magnetotail, J. Geophys. Res. - Space Phys., 118, 4804-4810, 2013.

226.	Chenglong Shen, Yuming Wang, Zonghao Pan, Min Zhang, Pinzhong Ye, and S. Wang, Full halo coronal mass ejections: Do we need to correct the projection effect in terms of velocity?, J. Geophys. Res. - Space Phys., 118, 1-8, 2013. (doi:.1002/2013JA018872)

225.	Su, Z. P., Zhu, H., Xiao, F. L., Zheng, H. N., Shen, C., Wang, Y. M., and Wang, S., Latitudinal dependence of nonlinear interaction between electromagnetic ion cyclotron wave and radiation belt relativistic electrons, J. Geophys. Res. - Space Phys., 118, 3188-3202, 2013.

224.	Zhenpeng Su, Hui Zhu, Fuliang Xiao, Huinan Zheng, Chao Shen, Yuming Wang, and and Shui Wang, latitudinal dependence of nonlinear interaction between electromagnetic ion cyclotron wave and radiation belt relativistic electrons, J. Geophys. Res. - Space Phys., 118, 1-15, 2013.

223.	Z. J. Rong, W. X. Wan, C. Shen, T. L. Zhang, A. T. Y. Lui, Yuming Wang, M. W. Dunlop, Y. C. Zhang, and Q.-G. Zong, Method for inferring the axis orientation of cylindrical magnetic flux rope based on single-point measurement, J. Geophys. Res. - Space Phys., 118, 1-13, doi:10.1029/2012JA018079, 2013.

222.	Chenglong Shen, Yuming Wang, Zonghao Pan, Min Zhang, Pinzhong Ye, and S. Wang, Full halo coronal mass ejections: Do we need to correct the projection effect in terms of velocity?, J. Geophys. Res. - Space Phys., 118, 6858-6865, doi:10.1002/2013JA018872, 2013.

221.	Su, Z. P., Zhu, H., Xiao, F. L., Zheng, H. N., Shen, C., Wang, Y. M., and Wang, S., Latitudinal dependence of nonlinear interaction between electromagnetic ion cyclotron wave and radiation belt relativistic electrons, J. Geophys. Res. - Space Phys., 118, 3188-3202, doi:10.1002/jgra.50289, 2013.

220.	Rui Liu, Dynamical Processes at the Vertical Current Sheet behind an Erupting Flux Rope, Mon. Not. R. Astron. Soc., 434, 1309-1320, 2013. (doi: 10.1093/mnras/stt1090)

219.	Weng, C. J.; Lee, L. C.; Kuo, C. L.; Wang, C. B., Effects of ion-neutral collisions on Alfven waves: The presence of forbidden zone and heavy damping zone, Phys. Plasmas, 20, 2013.

218.	Lu, S., Quanming Lu, C. Huang, and S. Wang, The transfer between electron bulk kinetic energy and thermal energy in collisionless magnetic reconnection, Phys. Plasmas, 20, 061203, 2013.

217.	Gao, X. L., Quanming Lu, X. Li, L. C. Shan, and S. Wang, Parametric instability of a monochromatic Alfven wave: Perpendicular decay in low beta plasma, Phys. Plasmas, 20, 072902, 2013.

216.	Gao, X.L., Quanming Lu, X. Tao, Y. F. Hao, and S. Wang, Effects of alpha beam on the parametric decay of a parallel propagating circularly polarized Alfven wave: hybrid simulations, Phys. Plasmas, 20, 092106, 2013.

215.	Yang, Z. W., Quanming Lu, X. L. Gao, C. Huang, H. G. Yang, Y. Liu, H. Q. Hu, and D. S. Han, Magnetic ramp scale at supercritical collisionless shocks: Full particle electromagnetic simulations, Phys. Plasmas, 20, 092116, 2013.

214.	Lu, S., Quanming Lu, Q. L. Dong, C. Huang, S. Wang, J. Q. Zhu, Z. M. Sheng, and J. Zhang, Particle-in-cell simulations of magnetic reconnection in laser-plasma experiments on SG-II facility, Phys. Plasmas, 20, 112110, 2013.

213.	Chenglong Shen, Chijian Liao, Yuming Wang, Pinzhong Ye, and Shui Wang, Source region of the decameter--Hectometric type II radio burst: Shock--streamer interaction region, Sol. Phys., 282, 543-552,Doi:10.1007/s11207-012-0161-z, 2013.

212.	Chenglong Shen, Chijian Liao, Yuming Wang, Pinzhong Ye, and Shui Wang, Source region of the decameter-Hectometric type II radio burst: Shock-streamer interaction region, Sol. Phys., 282, 543-552, doi:10.1007/s11207-012-0161-z, 2013.
Abstract.

211.	苏振鹏，肖伏良，郑惠南, 辐射带高能电子动力学演化模型, 《空间物理学进展》, 第四卷, 410-429, 2013.

210.	史良文, 申成龙, 汪毓明, and 沈芳, 太阳风扰动传输模式研究进展, 天文学进展, 31, 3, 2013.

2012 Top

209.	Wu, Mingyu, Quanming Lu, J. Zhu, A. M. Du, and S. Wang, The magnetic structures of electron phase-space holes formed in the electron two-stream instability, Astrophys. Space Sci., 338, 81-85, 2012.

208.	Lin, Y., J. Johnson, X. Y. Wang, and Quanming Lu, Simulation of mode conversion at the magnetopause, Chin. Sci. Bull., 57, 1375-1383, 2012.

207.	Chenglong Shen, Yuming Wang, Shui Wang, Ying Liu, Rui Liu, Angelos Vourlidas, Bin Miao, Pinzhong Ye, Jiajia Liu, and Zhenjun Zhou, Super-elastic Collision of Large-scale Magnetized Plasmoids in The Heliosphere, Nature Physics*, 8, 923-928,DOI:10.1038/NPHYS2440, 2012.

206.	Xiao, F. L., Zong, Q.-G., Su, Z. P., He, Z. G., Wang, C. R., and Tang, L. J., Correlated observations of intensified whistler waves and electron acceleration around the geostationary orbit, Plasma Phys. Control. Fusion, 54, 035004, 2012.

205.	Jiajia Liu, Zhenjun Zhou, Yuming Wang, Rui Liu, Bin Wang, Chijian Liao, Chenglong Shen, Huinan Zheng, Bin Miao, Zhenpeng Su, and S. Wang, Slow Magneto-acoustic Waves Observed above Quiet-Sun Region in a Dark Cavity, Astrophys. J., 758, L26, 2012.

204.	Liu, J. J., Zhou, Z. J., Wang, Y. M., Liu, R., Wang, B., Liao, C. J., Shen, C. L., Zheng, H. N., Miao, B., Su, Z. P., and Wang, S., Slow magneto-acoustic waves observed above quiet-sun region in a dark cavity, Astrophys. J., 758, L26, 2012.

203.	Rui Liu, Chang Liu, Tibor Torok, Yuming Wang, and Haimin Wang, Contracting and Erupting Components of Sigmoidal Active Regions, Astrophys. J., 757, 150, 2012.

202.	Rui Liu, Chang Liu, Tibor Torok, Yuming Wang, and Haimin Wang, Contracting and Erupting Components of Sigmoidal Active Regions, Astrophys. J., 757, 150, 2012.

201.	Rui Liu, Bernhard Kliem, Tibor Torok, Chang Liu, Viacheslav S. Titov, Roberto Lionello, Jon A. Linker, and Haimin Wang, Slow Rise and Partial Eruption of a Double-Decker Filament. I Observations and Interpretation, Astrophys. J., 756, 59, 2012.

200.	Sung-Hong Park, Kyung-Suk Cho, Su-Chan Bong, Pankaj Kumar, Jongchul Chae, Rui Liu, and Haimin Wang, The Occurrence and Speed of CMEs Related to Two Characteristic Evolution Patterns of Helicity Injection in their Solar Source Regions, Astrophys. J., 750, article id. 48, 2012. (http://adsabs.harvard.edu/abs/2012ApJ...750...48P)

199.	Shuo Wang, Chang Liu, Rui Liu, Na Den, Yang Liu, and Haimin Wang, Response of the Photospheric Magnetic Field to the X2.2 Flare on 2011 February 15, Astrophys. J., 745, L17, 2012. (http://adsabs.harvard.edu/abs/2012ApJ...745L..17W)

198.	Chang Liu, Na Deng, Rui Liu, Jeongwoo Lee, Thomas Wiegelmann, Ju Jing, Yan Xu, Shuo Wang, and Haimin Wang, Rapid Changes of Photospheric Magnetic Field after Tether-cutting Reconnection and Magnetic Implosion, Astrophys. J., 745, L4, 2012. (http://adsabs.harvard.edu/abs/2012ApJ...745L...4L)

197.	Kai Liu, Yuming Wang, Chenglong Shen, and Shui Wang, Critical Height for the Destabilization of Solar Prominences: Statistical Results from STEREO Observations, Astrophys. J., 744, 168, 2012.

196.	Kai Liu, Yuming Wang, Chenglong Shen, and Shui Wang, Critical Height for the Destabilization of Solar Prominences: Statistical Results from STEREO Observations, Astrophys. J., 744*, 168(10pp), 2012.
Abstract. At which height is a prominence inclined to be unstable, or where is the most probable critical height for the prominence destabilization? This question was statistically studied based on 362 solar limb prominences well recognized by Solar Limb Prominence Catcher and Tracker from 2007 April to the end of 2009. We found that there are about 71% disrupted prominences (DPs), among which about 42% of them did not erupt successfully and about 89% of them experienced a sudden destabilization process. After a comprehensive analysis of the DPs, we discovered the following: (1) Most DPs become unstable at a height of 0.060.14 R from the solar surface, and there are two most probable critical heights at which a prominence is very likely to become unstable, the first one is 0.13 R and the second one is 0.19 R . (2) An upper limit for the erupting velocity of eruptive prominences (EPs) exists, which decreases following a power law with increasing height and mass; accordingly, the kinetic energy of EPs has an upper limit too, which decreases as the critical height increases. (3) Stable prominences are generally longer and heavier than DPs, and not higher than 0.4 R . (4) About 62% of the EPs were associated with coronal mass ejections (CMEs); but there is no difference in apparent properties between EPs associated with CMEs and those that are not. We acknowledge the use of data from STEREO/SECCHI, and we are also grateful to the developers of SLIPCAT. We thank Dr. B. C. Low for his reading and valuable comments, and the anonymous referee for his/her constructive comments. This research is supported by grants from the 973 key project 2011CB811403, NSFC 41131065, 40904046, 40874075, and 41121003, the CAS 100-talent program, KZCX2-YW-QN511 and startup fund, FANEDD 200530, and the fundamental research funds for the central universities.

195.	Jiajia Liu, Zhenjun Zhou, Yuming Wang, Rui Liu, Bin Wang, Chijian Liao, Chenglong Shen, Huinan Zheng, Bin Miao, Zhenpeng Su, and S. Wang, Slow Magnetoacoustic Waves Observed above a Quiet-Sun Region in a Dark Cavity, Astrophys. J. Lett., 758, L26, 2012. (http://adsabs.harvard.edu/abs/2012ApJ...758L..26L)

194.	Jiajia Liu, Zhenjun Zhou, Yuming Wang, Rui Liu, Bin Wang, Chijian Liao, Chenglong Shen, Huinan Zheng, Bin Miao, Zhenpeng Su, and S. Wang, Slow Magnetoacoustic Waves Observed above a Quiet-Sun Region in a Dark Cavity, Astrophys. J. Lett., 758*, L26(6pp), 2012.

193.	Su, Y. Q., and Quanming Lu, Cross-Shock Electrostatic Potential and Ion Reflection in Quasi-Parallel supercritical collisionless shock, Chinese Phys. Lett., 29, 089601, 2012.

192.	Zhu, H., Su, Z. P., and Zheng, H. N., Normal-angle dependence of the interaction between radiation belt electrons and fast magnetosonic waves, Chinese Phys. Lett., 29, 109401, 2012.

191.	ZHU Hui, SU Zhen-Peng, and ZHENG Hui-Nan, Normal-Angle Dependence of the Interaction between Radiation Belt Electrons and Fast Magnetosonic Waves, Chinese Phys. Lett., 29, 109401, 2012.

190.	Zhang, T. L., W. Baumjohann, W. L. Teh, R. Nakamura, C. T. Russell, J. G. Luhmann, K. H. Glassmeier, E. D. Dubinin, H. Y. Wei, A. M. Du, Quanming Lu, S. Wang, and M. Balikhin, Giant flux ropes observed in the magnetized ionosphere at Venus, Geophys. Res. Lett., 39, L23103, 2012.

189.	Xiao, F. L., Zhang, S., Su, Z. P., He, Z. G., and Tang, L. J., Rapid acceleration of radiation belt energetic electrons by Z-mode waves, Geophys. Res. Lett., 39, L03103, 2012.

188.	Wang, R. S., R. Nakamura, Quanming Lu, A. M. Du, T. L. Zhang, and W. Baumjohann et al., Asymmetry in the current sheet and secondary magnetic flux ropes during guide field magnetic reconnection, J. Geophys. Res. - Space Phys., 117, A07223, 2012.

187.	Yang, Z. W., B. Lembege, and Quanming Lu, Impact of the rippling of a perpendicular shock front on ion dynanmics, J. Geophys. Res. - Space Phys., 117, A07222, 2012.

186.	Su, Y. Q., Quanming Lu, C. Huang, M. Y. Wu, X. L. Gao, and S. Wang, Particle acceleration and generation of diffuse superthermal ions at a quasi-parallel collisionless shock: Hybrid simulations, J. Geophys. Res. - Space Phys., 117, A08107, 2012.

185.	Su, Z. P., Zhu, H., Xiao, F. L., Zheng, H. N., Shen, C., Wang, Y. M., and Wang, S., Bounce-averaged advection and diffusion coefficients for monochromatic electromagnetic ion cyclotron wave: Comparison between test-particle and quasi-linear models, J. Geophys. Res. - Space Phys., 117, A09222, 2012.

184.	Zhu, H., Su, Z. P., Xiao, F. L., Zheng, H. N., Shen, C., Wang, Y. M., and Wang, S., Nonlinear interaction between ring current protons and electromagnetic ion cyclotron waves, J. Geophys. Res. - Space Phys., 117*, A12217, 2012.

183.	Zhenpeng Su, Hui Zhu, Fuliang Xiao, Huinan Zheng, Chao Shen, Yuming Wang, and and Shui Wang, Bounce-averaged advection and diffusion coefficients for monochromatic electromagnetic ion cyclotron wave: Comparison between test-particle and quasi-linear models, J. Geophys. Res. - Space Phys., 117, A09222, 2012.

182.	Hui Zhu, Zhenpeng Su, Fuliang Xiao, Huinan Zheng, Chao Shen, Yuming Wang, and Shui Wang, Nonlinear interaction between ring current protons and electromagnetic ion cyclotron waves, J. Geophys. Res. - Space Phys., 117, A12217, 2012.

181.	Zhenpeng Su, Hui Zhu, Fuliang Xiao, Huinan Zheng, C Chen, Yuming Wang, and S. Wang, Bounce-averaged advection and diffusion coefficients for monochromatic electromagnetic ion cyclotron wave: Comparison between test-particle and quasi-linear models, J. Geophys. Res. - Space Phys., 117, A09222, 2012.

180.	Hui Zhu, Zhenpeng Su, Fuliang Xiao, Huinan Zheng, Chao Shen, Yuming Wang, and Shui Wang, Nonlinear interaction between ring current protons and electromagnetic ion cyclotron waves, J. Geophys. Res. - Space Phys., 117, A12217, 2012.

179.	Chenglong Shen, Yuming Wang, Shui Wang, Ying Liu, Rui Liu, Angelos Vourlidas, Bin Miao, Pinzhong Ye, Jiajia Liu, and Zhenjun Zhou, Super-elastic Collision of Large-scale Magnetized Plasmoids in the Heliosphere, Nat. Phys., 8, 923, 2012. (http://adsabs.harvard.edu/abs/2012NatPh...8..923S)

178.	Chenglong Shen, Yuming Wang, Shui Wang, Ying Liu, Rui Liu, Angelos Vourlidas, Bin Miao, Pinzhong Ye, Jiajia Liu, and Zhenjun Zhou, Super-elastic Collision of Large-scale Magnetized Plasmoids in the Heliosphere, Nat. Phys.*, 8, 923-928, doi:10.1038/NPHYS2440, 2012. (Featured as the cover, http://www.nature.com/nphys/journal/v8/n12/covers/index.html; Highlighted in Editors' Choice of SCIENCE, http://science.sciencemag.org/content/338/6105/twil;)
Abstract. A super-elastic collision is an unusual process in which some mechanism causes the kinetic energy of the system to increase. Most studies have focused on solid-like objects, and have rarely considered gases or liquids, as the collision of these is primarily a mixing process. However, magnetized plasmoids are different from ordinary gases—as cross-field diffusion is effectively prohibited—but it remains unclear how they behave during a collision. Here we present a comprehensive picture of a unique collision between two coronal mass ejections in the heliosphere, which are the largest magnetized plasmoids erupting from the Sun. Our analysis reveals that these two magnetized plasmoids collided as if they were solid-like objects, with a likelihood of 73% that the collision was super-elastic. The total kinetic energy of the plasmoid system increased by about 6.6% through the collision, significantly influencing its dynamics.

177.	Wu, C. S.; Wang, C. B.; Wu, D. J.; Lee, K. H., Resonant wave-particle interactions modified by intrinsic Alfvenic turbulence, Phys. Plasmas, 19, 2012.

176.	Gao, X. L., Quanming Lu, X. Li, C. Huang, and S. Wang, Heating of the background plasma by obliquely propagating Alfven waves excited in the electromagnetic alpha/proton instability, Phys. Plasmas, 19, 032901, 2012.

175.	Huang, C., Quanming Lu, H. Zhang, M. Y. Wu, Q. L. Dong, S. Lu, and S. Wang, Kinetic simulations of the structures of magnetic island in multiple X line guide field reconnection, Phys. Plasmas, 19, 042111, 2012.

174.	Gao, X. L., Quanming Lu, M. Y. Wu, and S. Wang, Ion stochastic heating by obliquely propagating magnetosonic waves, Phys. Plasmas, 19, 062111, 2012.

173.	Su, Y. Q., Quanming Lu, X. L. Gao, C. Huang, and S. Wamg, Ion dynamics at supercritical quasi-parallel shocks: hybrid simulations, Phys. Plasmas, 19, 092108, 2012.

172.	Dong, Q. L., S. J. Wang, Quanming Lu, C. Huang, and D. W. Yuan et al., Plasmoid ejection and secondary current sheet generation from magnetic reconnection in laser-plasma interaction, Phys. Rev. Lett., 108, 215001, 2012.

171.	Zhang, T. L., Quanming Lu, W. Baumjohann, C. T. Rusell, A. Fedorov, S. Barabash, A. J. Coates, A. M. Du, J. B. Cao, R. Nakamura, W. L. Teh, R. S. Wang, X. K. Dou, S. Wang, K. H. Glassmeier, H. U. Auster, and M. Balikhin, Magnetic reconnection in the near Venusian magnetotail, Science, 336, 567, doi:10.1126/science.1217013, 2012.

2011 Top

170.	Lu, S., Quanming Lu, Y. Cao, C. Huang, J. L. Xie, and S. Wang, The effects of the guide field on the structures of electron density depletions in collisionless magnetic reconnection, Chinese Science Bulletin, 56, 48-52, 2011.

169.	Quanming Lu, R. S. Wang, J. L. Xie, C. Huang, S. Lu, and S. Wang, Electron dynamics in collisionless magnetic reconnection, Chinese Science Bulletin, 56, 1174-1181, 2011. (review paper)

168.	Quanming Lu (eds.), Space Physics and Space Weather, Chinese Science Bulletin, 56, 1173, 2011.

167.	Huang, C., Quanming Lu, Z. W. Yang, M. Y. Wu, Q. L. Dong, and S. Wang, The evolution of electron current sheet and formation of secondary islands in guide field reconnection, Nonlinear Processes in Geophysics, 18, 727-733, 2011.

166.	Rui Liu, Dynamics of solar eruptive filaments, ProQuest, UMI Dissertation Publishing, , 2011. (260 pages; ISBN: 1243618000 / 978-1-243-61800-9)

165.	Rui Liu, Tong-Jiang Wang, Jeongwoo Lee, Guillermo Stenborg, Chang Liu, Sung-Hong Park, and Haimin Wang, Observing the reconnection region in a transequatorial loop system, Research in Astronomy and Astrophysics, 11, 1209-1228, 2011. (http://adsabs.harvard.edu/abs/2011RAA....11.1209L)

164.	Yuan-Deng Shen, Yu Liu, and Rui Liu, A time series of filament eruptions observed by three eyes from space: from failed to successful eruptions, Research in Astronomy and Astrophysics, 11, 594-606, 2011. (http://adsabs.harvard.edu/abs/2011RAA....11..594S)

163.	Quanming Lu and C. Wang (eds.), A collected works on the solar-terrestrial space physics, University of Science and Technology of China Press, Hefei, January, 2011. (book)

162.	Liu, Yong C.-M., M. Opher, Yuming Wang, and T. I. Gombosi, Downstream structure and evolution of a simulated CME-driven sheath in the solar corona, Astron. & Astrophys., 527, A46, doi: 10.1051/0004-6361/201014384, 2011.
Abstract. Context. The transition of the magnetic field from the ambient magnetic field to the ejecta in the sheath downstream of a coronal mass ejection (CME)-driven shock is analyzed in detail. The field rotation in the sheath occurs in a two-layer structure. In the first layer, Layer 1, the magnetic field rotates in the coplanarity plane (plane of shock normal and the upstream magnetic field), and in Layer 2 rotates o this plane. We investigate the evolution of the two layers as the sheath evolves away from the Sun. Aims. In situ observations have shown that the magnetic field in the sheath region in front of an Interplanetary coronal mass ejection (ICME) form a planar magnetic structure, and the magnetic field lines drape around the flux tube. Our object is to investigate the magnetic configuration of the CME near the sun. Methods. We used a 3D Magnetohydrodynamics (MHD) simulation code, the space weather modeling framework (SWMF) to simulate the propagation of CMEs and the shock driven by it. Results. Close to the Sun, Layer 2 dominates the width of the sheath, diminishing its importance as the sheath evolves away from the Sun, consistent with observations at 1AU.

161.	Wu Ji, Sun Weiying, Zheng Jianhua, Zhang Cheng, Liu Hao, Yan Jingye, Wang Chi, Wang Chuanbing, and Wang Shui, Imaging interplanetary CMEs at radio frequency from solar polar orbit, Adv. Space Res., , doi:10.1016/j.asr.2011.05.001, 2011.

160.	Chang Liu, Na Deng, Rui Liu, Ignacio Ugarte-Urra, Shuo Wang, and Haimin Wang, A Standard-to-blowout Jet, Astrophys. J., 735, L18, 2011. (http://adsabs.harvard.edu/abs/2011ApJ...735L..18L)

159.	Gao, X. L., Quanming Lu, and S. Wang, Dynamics of charged particles and perpendicular diffusion in turbulent magnetic field, Astrophys. & Space Sci., 330, Doi:10.1007/s10509-011-0758-y, 2011.

158.	Gui, Bin, Chenglong Shen, Yuming Wang, Pinzhong Ye, and S. Wang, Correction of projection effect of CMEs in velocity: Comparing of Forward modeling method and simple angular correction method (Chinese Version), Chinese J. Space Sci., 31(2), 154-164, 2011.

157.	Gui, Bin, Chenglong Shen, Yuming Wang, Pinzhong Ye, and S. Wang, The Forward Modeling Method of CME and Discussion about the Projection Modified Method, Chinese J. Space Sci., 31 (2), 154-164, 2011.
Abstract. In this paper, the three-dimension velocity of 21 well-structured Corona Mass Ejections (CMEs) were obtained by Forward modeling based on STEREO-SECCHI observations during 2007-2008. By measuring the height of the projected front in STEREO-A and STEREO-B sky plane and using the projection modified method, modified velocity of these CMEs, which treated as ‘3D’ velocity before, were also obtained. Comparing the 3D velocity gotten from the Forward Modeling method and the modified velocity, we found that: (1) The 3D velocity and the modified velocity are almost the same when angular distance, which is defined as the angle between the line connecting CME source region and Sun center and the line connecting observer and sun center, is greater than 50 degree. (2) When the angular distance is less than 50 degree, the difference is obvious. The Second result shows that the modified method can not be used for the CMEs with angular distance less than 50 degree. We also found that the projected velocity is almost the same as the 3D velocity when the angular distance is greater than 65 degree. This result implies that the CME event with angular distance larger than 65 degree could be treated as a limb event.

156.	Xiao, F. L., He, Z. G., Zhang, S., Su, Z. P., and Chen, L. X., Diffusion simulation of outer radiation belt electron dynamics induced by superluminous L-O mode waves, Chinese Phys. Lett., 28, 039401, 2011.

155.	Wang Bin, Wang C. B., Yoon P. H., and Wu C. S., Stochastic heating and acceleration of minor ions by Alfvén waves, Geophys. Res. Lett., 38, Issue 10, CiteID L10103, 2011.

154.	Su, Z. P., Xiao, F. L., Zheng, H. N., and Wang, S., CRRES observation and STEERB simulation of the 9 October 1990 electron radiation belt dropout event, Geophys. Res. Lett., 38, L06106, 2011.

153.	Shaikh, D., I. S. Veselovsky, Quanming Lu, and G. P. Zank, From micro- to macro-scales in the heliosphere and magnetospheres, in IAGA Special Sopron Book Series, the Sun, the solar wind, and the heliosphere, Volume 4, Part 5, 177-197, 2011.

152.	Su, Z. P., Zheng, H. N., Chen, L. X., and Wang, S., Numerical simulations of storm-time outer radiation belt dynamics by wave-particle interactions including cross diffusion, J. Atoms. Sol.-Terres. Phys., 73, 95-105, 2011.

151.	Xiao, F. L., Chen, L. X., He, Y. H., Su, Z. P., and Zheng, H. N., Modeling for precipitation loss of ring current protons by electromagnetic ion cyclotron waves, J. Atoms. Sol.-Terres. Phys., 73, 106-111, 2011.

150.	Du, A. M., R. Nakamura, T. L. Zhang, E. Panov, W. Baumjohann, H. Luo, W. Y. Xu, Quanming Lu, M. Volwerk, A. Retino, B. Zieger, V. Angelopoulos, K. Glassmeier, J. McFadden, and D. Larson, Fast Tailward Flows in the Plasma Sheet Boundary Layer during a Substorm on March 9, 2008: THEMIS Observations, J. Geophys. Res. - Space Phys., 116, A03216, 2011.

149.	Quanming Lu, L. C. Shan, C. L. Shen, T. L. Zhang, Y. R. Li, and S. Wang, Velocity distributions of superthermal electrons fitted with a power law function in the magnetosheath: Cluster observaions, J. Geophys. Res. - Space Phys., 116, A03224, 2011.

148.	Wu, M. Y., Quanming Lu, A. M. Du,, J. L. Xie,, and S. Wang, The evolution of the magnetic structures in electron phase-space holes: two-dimensional particle-in-cell simulations, J. Geophys. Res. - Space Phys., 116, A10208, 2011.

147.	Yang, Z. W, B. Lembege, and Quanming Lu, Impact of the nonstationarity of a supercritical perpendicular collisionless shock on the dynamics and energy spectra of pickup ions, J. Geophys. Res. - Space Phys., 116, A08216, 2011.

146.	Yang, Z. W., B. Lembege, and Quanming Lu, Acceleration of heavy ions by perpendicular collisionless shocks: Impact of the shock front nonstationarity, J. Geophys. Res. - Space Phys., 116, A10202, 2011.

145.	Quanming Lu, Lican Shan, Chenlong Shen, Tielong Zhang, Yiren Li, and Shui Wang, Velocity distributions of superthermal electrons fitted with a power law function in the magnetosheath: Cluster observations”, J. Geophys. Res. - Space Phys., 116, A03224, doi:10.1029/2010JA016118, 2011.
Abstract.

144.	Yuming Wang, Caixia Chen, Bin Gui, Chenglong Shen, Pinzhong Ye, and S. Wang, Statistical Study of CME Source Locations: I. Understanding CMEs Viewed in Coronagraphs, J. Geophys. Res. - Space Phys., 116, A04104, 2011.

143.	Caixia Chen, Yuming Wang, Chenglong Shen, Pinzhong Ye, Jie Zhang, and S. Wang, Statistical Study of Coronal Mass Ejection Source Locations: II. Role of Active Regions in CME Production, J. Geophys. Res. - Space Phys., 116, A12108, 2011. (10.1029/2011JA016844)

142.	Su, Z. P., Xiao, F. L., Zheng, H. N., and Wang, S., Radiation belt electron dynamics driven by adiabatic transport, radial diffusion, and wave-particle interactions, J. Geophys. Res. - Space Phys., 116, A04205, 2011.

141.	Su, Z. P., Zong, Q.-G., Yue, C., Wang, Y. F., Zhang, H., and Zheng, H. N., Proton auroral intensification induced by interplanetary shock on 7 November 2004, J. Geophys. Res. - Space Phys., 116, A08223, 2011.

140.	Wang, C. R., Zong, Q.-G., Xiao, F. L., Su, Z. P., Wang, Y. F., and Yue, C., The relations between magnetospheric chorus and hiss inside and outside plasmasphere boundary layer: Cluster observation, J. Geophys. Res. - Space Phys., 116, A07221, 2011.

139.	Yuming Wang, Caixia Chen, Bin Gui, Chenglong Shen, Pinzhong Ye, and S. Wang, Statistical Study of Coronal Mass Ejection Source Locations: Understanding CMEs Viewed in Coronagraphs, J. Geophys. Res. - Space Phys., 116, A04104, doi: 10.1029/2010JA016101, 2011.
Abstract.

138.	F. Shen, X. S. Feng, Yuming Wang, S. T. Wu, W. B. Song, J. P. Guo, and Y. F. Zhou, Three-dimensional MHD simulations of two coronal mass ejections' propagation and Interaction Using a successive magnetized plasma blobs model, J. Geophys. Res. - Space Phys., 116, A09103, doi:10.1029/2011JA016584, 2011.
Abstract. A threedimensional (3D), timedependent, numerical magnetohydrodynamic (MHD) model is used to investigate the evolution and interaction of two coronal mass ejections (CMEs) in the nonhomogeneous ambient solar wind. The background solar wind is constructed on the basis of the selfconsistent source surface with observed line of sight of magnetic field and density from the source surface of 2.5 Rs to Earth's orbit (215 Rs) and beyond. The two successive CMEs occurring on 28 March 2001 and forming a multiple magnetic cloud in interplanetary space are chosen as a test case, in which they are simulated by means of a two highdensity, highvelocity, and high temperature magnetized plasma blobs model, and are successively ejected into the nonhomogeneous background solar wind medium along different initial launch directions. The dynamical propagation and interaction of the two CMEs between 2.5 and 220 Rs are investigated. Our simulation results show that, although the two CMEs are separated by 10 h, the second CME is able to overtake the first one and cause compound interactions and an obvious acceleration of the shock. At the L1 point near Earth the two resultant magnetic clouds in our simulation are consistent with the observations by ACE. In this validation study we find that this 3D MHD model, with the selfconsistent source surface as the initial boundary condition and the magnetized plasma blob as the CME model, is able to reproduce and explain some of the general characters of the multiple magnetic clouds observed by satellite. Acknowledgment. This work is jointly supported by NationalNatural Science Foundation of China (41174150, 41031066, 41074121, 40921063, 40874077, 40890162 and 40874091), the Specialized Research Fund for State Key Laboratories and the Public science and technology research funds projects of ocean (201005017). Y. Wang is supported by 973 Key Project 2011CB811403. S. T. Wu is supported by AFOSR grant FA95500710468, NSF grant ATM0754378, and NSO/AURA grant C10569A, which is a subaward of NSF Award 0132798. We thank the SOHO/LASCO team for letting us use their data. SOHO is a mission of international collaboration between ESA and NASA. The Wilcox Solar Observatory (WSO) data used in this study were obtained via the Web site http://wso.stanford.edu/synopticl.html for CR 1974. The WSO is currently supported by NASA. We also thank ACE Science Center (ASC; http://www.srl.caltech.edu/ACE/ASC/), from which we downloaded the hourly average solar wind data by ACE. The numerical calculation was completed on our SIGMA Cluster computing system. We are very grateful to our anonymous reviewers for the constructive and helpful comments.

137.	Caixia Chen, Yuming Wang, Chenglong Shen, Pinzhong Ye, Jie Zhang, and S. Wang, Statistical study of coronal mass ejection source locations: 2. Role of active regions in CME production, J. Geophys. Res. - Space Phys., 116*, A12108, doi:10.1029/2011JA016844, 2011.
Abstract.

136.	Du, A. M., M. Y. Wu, Quanming Lu, C. Huang, and S. Wang, Transverse instability and magnetic structures associated with electron phase space holes, Phys. Plasmas, 18, 032104, 2011.

135.	Lu, S., Quanming Lu, X. Shao, P. H. Yoon, and S. Wang, Weibel Instability and structures of magnetic island in anti-parallel collisionless magnetic reconnection, Phys. Plasmas, 18, 072105, 2011.

134.	Quanming Lu, X. L. Gao, and X. Li, Comment on “ Heating of ions by low-frequency Alfven waves in partially ionized plasmas” [Phys. Plasmas 18, 030702(2011)], Phys. Plasmas, 18, 084703, 2011.

133.	Bin Gui, Chenglong Shen, Yuming Wang, Pinzhong Ye, Jiajia Liu, and Shui Wang1, A Quantitative Analysis of the CME Deflections in the Corona, Sol. Phys., 271, 111 - 139, 2011.
Abstract. n this paper, ten CME events viewed by the STEREO twin spacecraft are analyzed to study the deflections of CMEs during their propagation in the corona. Based on the three-dimensional information of the CMEs derived by the graduated cylindrical shell (GCS) model (Thernisien, Howard, and Vourlidas in Astrophys. J. 652, 1305, 2006), it is found that the propagation directions of eight CMEs had changed. By applying the theoretical method proposed by Shen et al. (Solar Phys. 269, 389, 2011) to all the CMEs, we found that the deflections are consistent, in strength and direction, with the gradient of the magnetic energy density. There is a positive correlation between the deflection rate and the strength of the magnetic energy density gradient and a weak anti-correlation between the deflection rate and the CME speed. Our results suggest that the deflections of CMEs are mainly controlled by the background magnetic field and can be quantitatively described by the magnetic energy density gradient (MEDG) model.

132.	Bin Gui, Chenglong Shen, Yuming Wang, Pinzhong Ye, Jiajia Liu, Shui Wang, and Xuepu Zhao, Quantitative Analysis of CME Deflections in the Corona, Sol. Phys., 271*, 111-139, doi:10.1007/s11207-011-9791-9, 2011.
Abstract. In this paper, ten CME events viewed by the STEREO twin spacecraft are analyzed to study the deflections of CMEs during their propagation in the corona. Based on the three-dimensional information of the CMEs derived by the graduated cylindrical shell (GCS) model (Thernisien, Howard, and Vourlidas in Astrophys. J. 652, 1305, 2006), it is found that the propagation directions of eight CMEs had changed. By applying the theoretical method proposed by Shen et al. (Solar Phys. 269, 389, 2011) to all the CMEs, we found that the deflections are consistent, in strength and direction, with the gradient of the magnetic energy density. There is a positive correlation between the deflection rate and the strength of the magnetic energy density gradient and a weak anti-correlation between the deflection rate and the CME speed. Our results suggest that the deflections of CMEs are mainly controlled by the background magnetic field and can be quantitatively described by the magnetic energy density gradient (MEDG) model. Acknowledgements We acknowledge the use of the data from STEREO/SECCHI and SOHO/MDI. We also acknowledge the use of the GCS model that was developed by A. Thernisien. We are grateful to the anonymous referee for his/her kind and constructive comments. This work is supported by grants from 973 key projects 2011CB811403, NSFC 40874075, 40904046, FANEDD 200530, CAS KZCX2-YW-QN511, 100-Talent program of CAS, and the fundamental research funds for the central universities.

131.	Z. H. Pan, C. B. Wang, Yuming Wang, and X. H. Xue, Correlation analyses between the characteristic time of gradual solar energetic particle events and the properties of associated coronal mass ejections, Sol. Phys., 270, 593-607, doi:10.1007/s11207-011-9763-0, 2011.
Abstract.

130.	Shen, Chenglong, Yuming Wang, Bin Gui, Pinzhong Ye, and Shui Wang, Kinematic Evolution of A Slow CME in Corona Viewed by STEREO-B on October 8, 2007, Sol. Phys., 269, 389－400,doi:0.1007/s11207-011-9715-8, 2011.
Abstract.

129.	Rui Liu, Yan Xu, and Haimin Wang, A Revisit of the Masuda Flare, Sol. Phys., 269, 67-82, 2011. (http://adsabs.harvard.edu/doi/10.1007/s11207-010-9688-z)

128.	Shen, Chenglong, Yuming Wang, Bin Gui, Pinzhong Ye, and Shui Wang, Kinematic Evolution of A Slow CME in Corona Viewed by STEREO-B on October 8, 2007, Sol. Phys., 269, 389-400, 2011.
Abstract. We studied the kinematic evolution of the 8 October 2007 CME in the corona based on observations from Sun Earth Connection Coronal and Heliospheric Investigation (SECCHI) onboard satellite B of Solar TErrestrial RElations Observatory (STEREO). The observational results show that this CME obviously deflected to a lower latitude region of about 30° at the beginning. After this, the CME propagated radially. We also analyze the influence of the background magnetic field on the deflection of this CME. We find that the deflection of this CME at an early stage may be caused by a nonuniform distribution of the background magnetic-field energy density and that the CME tended to propagate to the region with lower magnetic-energy density. In addition, we found that the velocity profile of this gradual CME shows multiphased evolution during its propagation in the COR1-B FOV. The CME velocity first remained constant: 23.1 km s-1 . Then it accelerated continuously with a positive acceleration of 7.6 m s-2 . Acknowledgements. We acknowledge the use of the data from STEREO/SECCHI. We thank Jie Zhang for helpful discussions. This work is supported by grants from the National Natural Science Foundation of China (40904046, 40874075, 40525014), the 973 National Basic Research Program (2011CB811403), Ministry of Education of China (200530), the Program for New Century Excellent Talents in University (NCET-08-0524), the Chinese Academy of Sciences (KZCX2-YW-QN511, KJCX2-YW-N28 and the startup fund) and the Fundamental Research Funds for the Central Universities.

127.	Pan, Z. H., Wang, C. B., Wang, Yuming, and Xue, X. H., Correlation Analyses Between the Characteristic Times of Gradual Solar Energetic Particle Events and the Properties of Associated Coronal Mass Ejections, Sol. Phys., , DOI 10.1007/s11207-011-9763-0, 2011.

2010 Top

126.	Xiao, F. L., Zong, Q.-G., Pu, Z. Y., Su, Z. P., Cao, J. B., He, J. S., Wang, Y. F., and Zheng, H. N., Electron acceleration by whistler-mode waves around the magnetic null during 3D reconnection, Plasma Phys. Control. Fusion, 52, 052001, 2010.

125.	Cheng-Long Shen, Jia Yao, Yu-Ming Wang, Pin-Zhong Ye, Xue-Pu Zhao, and Shui Wang, Influence of Coronal Holes on CMEs in Causing SEP Events, Research in Astronomy and Astrophysics (RAA), 10, 1049-1060, 2010.
Abstract. The issue of the inﬂuence of coronal holes (CHs) on coronal mass ejections (CMEs) in causing solar energetic particle (SEP) events is revisited. It is a continuation and extension of our previous work (Shen et al., 2006), in which no evident effect of CHs on CMEs in generating SEPs were found by statistically investigating 56 CME events. This result is consistent with the conclusion obtained by Kahler in 2004. In this paper, we extrapolate the coronal magnetic ﬁeld, deﬁne CHs as the regions consisting of only open magnetic ﬁeld lines and perform a similar analysis on this issue for totally 76 events by extending the study interval to the end of 2008. Three key parameters, CH proximity, CH area and CH relative position, are involved in the analysis. The new result conﬁrms the previous conclusion that CHs did not show any evident effect on CMEs in causing SEP events.

124.	Xiao, F. L., Zong, Q.-G., Su, Z. P., Tian, T., and Zheng, H. N., Latest progress on interactions between VLF/ELF waves and energetic electrons in the inner magnetosphere, Sci. China Earth Sci., 53, 317, 2010.

123.	Ding, J. Y., M. S. Madjarska, J. G. Doyle, and Quanming Lu, Chromospheric magnetic reconnection caused by photospheric flux emergence: implications for jet-like events formation, Astron. & Astrophys., 510, A111, 2010.

122.	Jie Zhang, Yuming Wang, and Yang Liu, Statistical Properties of Solar Active Regions Obtained from an Automatic Detection System and the Computational Biases, Astrophys. J., 723, 1006-1018, 2010.
Abstract. We have developed a computational software system to automate the process of identifying solar active regions (ARs) and quantifying their physical properties based on high-resolution synoptic magnetograms constructed from Michelson Doppler Imager (MDI; on board the SOHO spacecraft) images from 1996 to 2008. The system, based on morphological analysis and intensity thresholding, has four functional modules: (1) intensity segmentation to obtain kernel pixels, (2) a morphological opening operation to erase small kernels, which effectively remove ephemeral regions and magnetic fragments in decayed ARs, (3) region growing to extend kernels to full AR size, and (4) the morphological closing operation to merge/group regions with a small spatial gap. We calculate the basic physical parameters of the 1730 ARs identified by the auto system. The mean and maximum magnetic flux of individual ARs are 1.67 ×1022 Mx and 1.97 ×1023 Mx, while that per Carrington rotation are 1.83 ×1023 Mx and 6.96 ×1023 Mx, respectively. The frequency distributions of ARs with respect to both area size and magnetic flux follow a log-normal function. However, when we decrease the detection thresholds and thus increase the number of detected ARs, the frequency distribution largely follows a power-law function. We also find that the equatorward drifting motion of the AR bands with solar cycle can be described by a linear function superposed with intermittent reverse driftings. The average drifting speed over one solar cycle is 1. 83 ± 0. 04 yr-1 or 0.708 ± 0.015 m s-1 . We thank the anonymous referee for valuable comments. We acknowledge the usage of SOHO/MDI data. SOHO is a project of international cooperation between ESA and NASA. J.Z. is supported by NASA grants NNG07AO72G and NSF ATM-0748003. Y.M.W. is supported by 973-key-project 2006CB806304 and NSFC 40525014 of China.

121.	Li, X., Quanming Lu, Y. Chen, B. Li, and L. D. Xia, Kinetic Alfven wave and proton distribution function in the fast solar wind, Astrophys. J., 719, L190-L193, 2010.

120.	Wang, Yuming, Hao Cao, Junhong Chen, Tengfei Zhang, Sijie Yu, Huinan Zheng, Chenglong Shen, Jie Zhang, and S. Wang, Solar LImb Prominence CAtcher & Tracker (SLIPCAT): An Automated System and Its Preliminary Statistical Results, Astrophys. J., 717(2), 973-986, 2010.
Abstract.

119.	Wang, R. S., A. M. Du, Quanming Lu, X. D. Zhao, and H. Luo, Mid-tail magnetic reconnection triggering substorm: A case study, Chinese J. Geophys., 53, 1028-1033, 2010.

118.	Yang, Z. W., Quanming Lu, and S. Wang, Ion velocity distribution in a non-stationary perpendicular shock, Chinese Phys. Lett., 27, 019601, 2010.

117.	Wu, M. Y., Wu, H., Quanming Lu, and B. S. Xue, The effects of perpendicular thermal velocities on the transverse instability in electron phase space holes, Chinese Phys. Lett., 27, 095201, 2010.

116.	Wang, R. S., Quanming Lu, C. Huang, and S. Wang, Multispacecraft observation of electron pitch-angle distributions in magnetotail reconnection, J. Geophys. Res. - Space Phys., 115, A01209, 2010.

115.	Quanming Lu, L. H. Zhou, and S. Wang, Particle-in-cell simulations of whistler waves excited by an electron kappa distribution in space plasma, J. Geophys. Res. - Space Phys., 115, A02213, 2010.

114.	Li, X., and Quanming Lu, Heating and deceleration of minor ions in the extended fast solar wind by oblique Alfven waves, J. Geophys. Res. - Space Phys., 115, A08105, 2010.

113.	Wu, M. Y., Quanming Lu, C. Huang, and S. Wang, Transverse instability and perpendicular electric field in two-dimensional electron phase-space holes, J. Geophys. Res. - Space Phys., 115, A10245, 2010.

112.	Wang, R. S., Quanming Lu, X. Li, C. Huang, and S. Wang, Observations of energetic electrons up to 200 keV associated with a secondary island near the center of an ion diffusion region: A Cluster case study, J. Geophys. Res. - Space Phys., 115, A11201, 2010.

111.	Lu, Q. M., C. Huang, J. L. Xie, R. S. Wang, M. Y. Wu, A. Vaivads, and S. Wang, Features of separatrix regions in magnetic reconnection: Comparison of 2D particle-in-cell simulations and Cluster observations, J. Geophys. Res. - Space Phys., 115, A11208, 2010.

110.	Xiao, F. L., Su, Z. P., Zheng, H. N., and Wang, S., Three-dimensional simulations of outer radiation belt electron dynamics including cross diffusion terms, J. Geophys. Res. - Space Phys., 115, A05216, 2010.

109.	Su, Z. P., Xiao, F. L., Zheng, H. N., and Wang, S., STEERB: A three-dimensional code for storm-time evolution of electron radiation belt, J. Geophys. Res. - Space Phys., 115, A09208, 2010.

108.	Su, Z. P., Zheng, H. N., and Wang, S., A parametric study on the diffuse auroral precipitation by resonant interaction with whistler-mode chorus, J. Geophys. Res. - Space Phys., 115, A05219, 2010.

107.	Su, Z. P., Zheng, H. N., and Wang, S., Three dimensional simulation of energetic outer zone electron dynamics due to wave-particle interaction and azimuthal advection, J. Geophys. Res. - Space Phys., 115, A06203, 2010.

106.	Xiao, F. L., Su, Z. P., Chen, L. X., Zheng, H. N., and Wang, S., A parametric study on outer radiation belt electron evolution by superluminous R-X mode waves, J. Geophys. Res. - Space Phys., 115, A10217, 2010.

105.	Su, Z. P., Xiao, F. L., Zheng, H. N., and Wang, S., Combined radial diffusion and adiabatic transport of radiation belt electrons with arbitrary pitch-angles, J. Geophys. Res. - Space Phys., 115, A10249, 2010.

104.	Huang, C., Quanming Lu, and S. Wang, The mechanisms of electron acceleration in anti-parallel and guide field magnetic reconnection, Phys. Plasmas, 17, 072306, 2010.

103.	Wang, R. S., Quanming Lu, A. M. Du, and S. Wang, In situ observations of a secondary magnetic island in an ion diffusion region and associated energetic electrons, Phys. Rev. Lett., 104, 175003, 2010.

2009 Top

102.	Quanming Lu, Z. W. Yang, B. Lembege, and S. Wang, Ion acceleration in non-stationary shocks, AIP Conference Proceeding: Shock waves in Space and Astrophysical Environments, 1183, 39-46, 2009.

101.	Chen Tingdi, Xue Xianghui, and Dou Xiankang, A Mie-Rayleigh-Soudim Fluorescence Lidar system for atmospheric detecting, Advances in Geosciences: Atmospheric Science (AS)-v.10, , 2009. (Editors: J. H. Oh, Gyan Prakash Singh, Publisher: World Scientific Pub Co Inc), , 2009.

100.	Xiankang Dou, Xianghui Xue (Corresponding Author), Tingdi Chen, Weixing Wan, Xuewu Cheng, Tao Li, Cao Chen, Shican Qiu, and Zeyu Chen, A statistical study of sporadic sodium layer observed at Hefei, Ann. Geophys., 27, 2247-2257, 2009.

99.	Quanming Lu, Xing Li, and C. F. Dong, Ion Pickup by intrinic low-frequency Alfven waves with a spectrum, Chinese Physics B, 18, 2101, 2009.

98.	Huang, C., R. S. Wang, Quanming Lu, and S. Wang, Electron density hole and quadruple structure of By during collisionless magnetic reconnection, Chinese Science Bulletins, 54, 3852-3857, 2009.

97.	Guo, J., Z. W. Yang, Quanming Lu, and S. Wang, The nonlinear evolution of ion cyclotron waves in the Earth's magnetosheath, Plasma Sci. & Tech., 11, 274-278, 2009.

96.	Quanming Lu, Q. Hu, and G. P. Zank, The interaction of Alfven waves with perpendicular shock, Astrophys. J., 706, 687-692, 2009.

95.	Quanming Lu, and Liu Chen, Ion Heating by a spectrum of obliquely propagating low-frequency Alfven waves, Astrophys. J., 704, 743-749, 2009.

94.	Su, Z. P., Xiong, M., Zheng, H. N., and Wang, S., Propagation of interplanetary shock and its consequent geoeffectiveness, Chinese J. Geophys., 52, 591-598, 2009.

93.	Xiao, F. L., Tian, T., Chen, L. X., Su, Z. P., and Zheng, H. N., Evolution of ring current protons induced by electromagnetic ion cyclotron waves, Chinese Phys. Lett., 26, 119401, 2009.

92.	Su, Z. P. and Zheng, H. N., Resonant scattering of relativistic outer zone electrons by plasmaspheric plume electromagnetic ion cyclotron waves, Chinese Phys. Lett., 26, 129401, 2009.

91.	Su, Z. P., Zheng, H. N., and Xiong, M., Dynamic evolution of outer radiation belt electrons due to whistler-mode chorus, Chinese Phys. Lett., 26, 039401, 2009.

90.	Ming Xiong, Zhong Peng, Youqiu Hu, and Huinan Zheng, Response of the Earth's Magnetosphere and Ionosphere to Solar Wind Driver and Ionosphere Load: Results of Global MHD Simulations, Chinese Phys. Lett., 26, 015202, 2009.
Abstract. Three-dimensional global magnetohydrodynamic simulations of the solar wind-magnetosphere-ionosphere system are carried out to explore the dependence of the magnetospheric reconnection voltage, the ionospheric transpolar potential, and the field aligned currents (FACs) on the solar wind driver and ionosphere load for the cases with pure southward interplanetary magnetic field (IMF). It is shown that the reconnection voltage and the transpolar potential increase monotonically with decreasing Pedersen conductance (ΣP), increasing southward IMF strength (Bs) and solar wind speed (vsw). Moreover, both regions 1 and 2 FACs increase when Bs and vsw increase, whereas the two currents behave differently in response to ΣP. As ΣP increases, the region 1 FAC increases monotonically, but region 2 FAC shows a non-monotonic response to the increase of ΣP: it first increases in the range of (0,5) Siemens and then decreases for ΣP > 5 Siemens. Supported by the National Natural Science Foundation of China under Grant Nos 40831060, 40621003 and 40774077, the China Postdoctoral Science Foundation (20070420725), and K. C. Wong Education Foundation of Hong Kong.

89.	Xiankang Dou, Tao Li, Jiyao Xu, Hanli Liu, Xianghui Xue, Shui Wang, T. Leblanc, I. S.McDermid, A. Hauchecorne, P. Keckhut, C. Heinselman, W. Steinbrecht, M. G. Mlynczak, and J. M. Russell, Seasonal oscillations of middle atmosphere temperature observed by Rayleigh lidars and their comparisons with TIMED/SABER observations, J. Geophys. Res. - Space Phys., 114,D20103, doi:10.1029/2008JD011654., 2009.

88.	Yuming Wang, Jie Zhang, and Chenglong Shen, An analytical model probing the internal state of coronal mass ejections based on observations of their expansions and propagations, J. Geophys. Res. - Space Phys., 114, A10104, doi:10.1029/2009JA014360, 2009.
Abstract. In this paper, a generic self-similar flux rope model is proposed to probe the internalstate of CMEs in order to understand the thermodynamic process and expansion of CMEs in interplanetary space. Using this model, three physical parameters and their variations with heliocentric distance can be inferred based on coronagraph observations of CMEs' propagation and expansion. One is the polytropic index G of the CME plasma, and the other two are the average Lorentz force and the thermal pressure force inside CMEs. By applying the model to the 8 October 2007 CME observed by STEREO/SECCHI, we find that (1) the polytropic index of the CME plasma increased from initially 1.24 to more than 1.35 quickly and then slowly decreased to about 1.34; it suggests that there be continuously heat injected/converted into the CME plasma and the value of Gamma tends to be 4/3, a critical value inferred from the model for a force-free flux rope; (2) the Lorentz force directed inward while the thermal pressure force outward, and both of them decreased rapidly as the CME moved out; the direction of the two forces reveals that the thermal pressure force is the internal driver of the CME expansion, whereas the Lorentz force prevented the CME from expanding. Some limitations of the model and approximations are discussed meanwhile. Acknowledgments. We acknowledge the use of the data from STEREO/SECCHI. We thank James Chen and Yong C.-M. Liu for discussions and the referees for valuable comments. Y. Wang and J. Zhang are supported by grants from NASA NNG05GG19G, NNG07AO72G, and NSF ATM-0748003. Y. Wang and C. Shen also acknowledge the support of China grants from NSF 40525014, 973 key project 2006CB806304, and Ministry of Education 200530.

87.	Yang, Z. W., Quanming Lu, B. Lembege, S. Wang, Shock front nonstationarity and ion acceleration in supercritical perpendicular shock, J. Geophys. Res. - Space Phys., 114, A03111, 2009.

86.	Liu, C. X., S. P. Jin, F. S. Wei, Quanming Lu, and H. A. Yang, Plasmoid-like structures in multiple X line Hall MHD reconnection, J. Geophys. Res. - Space Phys., 114, A10208, 2009.

85.	Su, Z. P., Zheng, H. N., and Wang, S., Dynamic evolution of energetic outer zone electrons due to whistler-mode chorus based on a realistic density model, J. Geophys. Res. - Space Phys., 114, A07201, 2009.

84.	Su, Z. P., Zheng, H. N., and Wang, S., Evolution of electron pitch angle distribution due to interactions with whistler-mode chorus following substorm injections, J. Geophys. Res. - Space Phys., 114, A08202, 2009.

83.	Xiao, F. L., Su, Z. P., Zheng, H. N., and Wang, S., Modeling of outer radiation belt electrons by multi-dimensional diffusion process, J. Geophys. Res. - Space Phys., 114, A03201, 2009.

82.	Ming Xiong, Huinan Zheng, and Shui Wang, Magnetohydrodynamic simulation of the interaction between two interplanetary magnetic clouds and its consequent geoeffectiveness: 2. Oblique collision, J. Geophys. Res. - Space Phys., 114, A11101, doi:10.1029/2009JA014079, 2009.
Abstract. The numerical studies of the interplanetary coupling between multiple magnetic clouds (MCs) are continued by a 2.5-dimensional ideal magnetohydrodynamic (MHD) model in the heliospheric meridional plane. The interplanetary direct collision (DC) / oblique collision (OC) between both MCs results from their same/different initial propagation orientations. Here the OC is explored in contrast to the results of the DC (Xiong et al., 2007). Both the slow MC1 and fast MC2 are consequently injected from the different heliospheric latitudes to form a compound stream during the interplanetary propagation. The MC1 and MC2 undergo contrary deflections during the process of oblique collision. Their deflection angles of $\|\delta \theta_1\|$ and $\|\delta \theta_2\|$ continuously increase until both MC-driven shock fronts are merged into a stronger compound one. The $\|\delta \theta_1\|$, $\|\delta \theta_2\|$, and total deflection angle $\Delta \theta$ ($\Delta \theta = \|\delta \theta_1\| + \|\delta \theta_2\|$) reach their corresponding maxima when the initial eruptions of both MCs are at an appropriate angular difference. Moreover, with the increase of MC2's initial speed, the OC becomes more intense, and the enhancement of $\delta \theta_1$ is much more sensitive to $\delta \theta_2$. The $\|\delta\theta_1\|$ is generally far less than the $\|\delta\theta_2\|$, and the unusual case of $\|\delta\theta_1\|\simeq\|\delta\theta_2\|$ only occurs for an extremely violent OC. But because of the elasticity of the MC body to buffer the collision, this deflection would gradually approach an asymptotic degree. As a result, the opposite deflection between the two MCs, together with the inherent magnetic elasticity of each MC, could efficiently relieve the external compression for the OC in the interplanetary space. Such deflection effect for the OC case is essentially absent for the DC case. Therefore, besides the magnetic elasticity, magnetic helicity, and reciprocal compression, the deflection due to the OC should be considered for the evolution and ensuing geoeffectiveness of interplanetary interaction among successive coronal mass ejections (CMEs). This work was supported by the National Natural Science Foundation of China (40774077), the National Key Basic Research Special Foundation of China (2006CB806304). M. Xiong was also supported by the China Postdoctoral Science Foundation (both special and general sponsorships) and the K. C.Wong Education Foundation of Hong Kong.

81.	Quanming Lu, Anmin Du, and Xing Li, Two-dimensional hybrid simulations of the oblique electromagnetic alpha/proton instability in the solar wind, Phys. Plasmas, 16, 042901, 2009.

80.	Yang, Z. W., Quanming Lu, and S. Wang, The evolution of the electric field at a nonstationary perpendicular shock, Phys. Plasmas, 16, 124502, 2009.

79.	Wang, C.B. and Wu, C. S., Pseudoheating of protons in the presence of Alfvénic turbulence, Phys. Plasmas, 16, 020703, 2009.

78.	Wu C.S., Yoon P.H., and Wang C.B., On nonresonant proton heating via intrinsic Alfvénic turbulence, Phys. Plasmas, 16, 054503, 2009.

77.	Wang Bin and Wang CB (Corresponding Author), Heating rate of ions via nonresonant interaction with turbulent Alfvén waves with ionization and recombination, Phys. Plasmas, 16, 2009.

76.	Yoon, PH, Wang, CB, and Wu, CS, Pitch-angle diffusion of ions via nonresonant interaction with Alfvénic turbulence, Phys. Plasmas, 16, 102102, 2009.

2008 Top

75.	Quanming Lu, Q. Hu, and G. P. zank, The interaction between Alfven waves and perpendoicular shocks, AIP proceedings:Particle Acceleration and Transport in the Heliosphere and Beyond, 1039, 321-326, 2008.

74.	Quanming Lu, S. S. Mao, X. L. Mao, and R. E. Russo, Theory analysis of wavelength dependence of laser-induced phase explosion of silicon, Journal of Applied Physics, 104, 083301, 2008.

73.	Tingdi CHEN, Xiankang DOU, and Xianghui XUE, Backscattering coefficient model and its application in rain rate retrival, Specify the Journal, 23, 803, 2008.

72.	Xianghui Xue,, Weixing Wan, Jiangang Xiong, and Xiankang Dou, The characteristics of the semi-diurnal tides in mesosphere/low-thermosphere (MLT) during 2002 at Wuhan (30.6oN, 114.4oE) -using Canonical Correlation Analysis technique, Adv. Space Res., 9, 1415-1422, 2008.

71.	Yuming Wang and Jie Zhang, A Statistical Study on Solar Active Regions Producing Extremely Fast Coronal Mass Ejections, Astrophys. J., 680, 1516, 2008.
Abstract. We present a statistical result on the properties of solar source regions that have produced 57 fastest front-side coronal mass ejections (CMEs) (speed 1500 km s-1 ) occurred from 1996 June to 2007 January. The properties of these fast-CME-producing regions, 35 in total, are compared with those of all 1143 active regions (ARs) in the period studied. An automated method, based on SOHO/MDI magnetic synoptic charts, is used to select and characterize the ARs. For each AR, a set of parameters are derived including the areas (positive, negative and total, denoted by A_P , A_N and A_T respectively), the magnetic fluxes (positive, negative and total, F_P , F_N and F_T respectively), the average magnetic field strength (B_avg), quasi-elongation (e) characterizing the overall shape of the AR, the number and length of polarity inversion lines (PILs, or neutral lines, N_PIL and L_PIL respectively), and the average and maximum of magnetic gradient on the PILs (GOP_avg and GOP_max respectively). Our statistical analysis shows a general trend between the scales of an AR and the likelihood of producing a fast CME, i.e., the larger the geometric size (A_T), the larger the magnetic flux (F_T), the stronger the magnetic field (B_avg), and/or the more complex the magnetic configuration (N_PIL and L_PIL), then the higher the possibility of producing a fast CME. When all ARs are sorted into three equally-numbered groups with low, middle and high values of these parameters, we find that, for all these AR parameters, more than 60% of extremely fast CMEs are from the high-value group. The two PIL parameters are the best indicators of producing fast CMEs, with more than 80% from the high value group. Acknowledgement. We acknowledge the use of the solar data from the MDI, LASCO, and EIT instruments on board SOHO spacecraft. The SOHO/LASCO data used here are produced by a consortium of the Naval Research Laboratory (USA), Max-Planck-Institut fuer Aeronomie (Germany), Laboratoire d'Astronomie (France), and the University of Birmingham (UK). SOHO is a pro ject of international cooperation between ESA and NASA. We also acknowledge the use of CME catalog generated and maintained at the CDAW Data Center by NASA and The Catholic University of America in cooperation with the Naval Research Laboratory, and the flare list compiled by the Space Environment Center of NOAA. This work is supported by NSF SHINE grant ATM-0454612 and NASA grant NNG05GG19G. Y. Wang is also supported by the grants from NSF of China (40525014) and MSTC (2006CB806304), and J. Zhang is also supported by NASA grants NNG04GN36G.

70.	Yang, Z. W., Quanming Lu, J. Guo, and S. Wang, Mechanism of ion acceleration at perpendicular collisionless shocks, Chinese J. Geophys., 51, 953-959, 2008.

69.	Guo, F., Quanming Lu, J. Guo, and S. Wang, Nonlinear evolution of lower-hybrid drift instability in Harris current sheet, Chinese Phys. Lett., 25, 2725-2728, 2008.

68.	Wang, R. S., Quanming Lu, J. Guo, and S. Wang, Spatial distribution of energetic electrons during magnetic reconnection, Chinese Phys. Lett., 25, 3083-3085, 2008.

67.	SU Zhen-Peng and ZHENG Hui-Nan, Simulation of Resonant Interaction Between Energetic Electrons and Whistler-mode Chorus In the Outer Radiation Belt, Chinese Phys. Lett., 25, 4493, 2008.
Abstract. In this study, we construct a realistic model to evaluate the chorus wave particle interaction in the outer radiation belt L=4.5. This model incorporates a plasmatrough number density model, a field-aligned density model and a realistic wave power and frequency model. We solve the 2-D bounce-averaged momentum-pitch-angle Fokker-Planck equation and show that whistler-mode chorus can be effective in acceleration of electrons, and enhance the phase space density for energies of ~1 MeV by a factor of 10 to 1000 in about two days, consistent with observation. We also demonstrate that ignorance of the electron number density variation along field line and magnetic local time in the previous work yields an overestimate of energetic electron phase space density by a factor 5~10 at large pitch-angle after two days, suggesting that a realistic plasma density model is very important to evaluate the evolution of energetic electrons in the outer radiation belt.

66.	Huinan Zheng, Z. P. Su, and Ming Xiong, Pitch angle distribution evolution of energetic electrons by whistler-mode chorus, Chinese Phys. Lett., 25, 3515-3518, 2008.

65.	Fuliang Xiao, C. L. Shen, Yuming Wang, Huinan Zheng, and S. Wang, Energetic electrons distribution fitted with a relativistic kappa-type function at geosynchronous orbit, J. Geophys. Res. - Space Phys., 113, A05203, doi:10.1029/2007JA012903, 2008.
Abstract. In this study, we utilize a recently introduced relativistic kappa-type (KT) distribution function to model the omnidirectional differential flux of energetic electrons observed by the SOPA instrument on board the 1989- 046 and LANL-01A satellites at geosynchronous orbit. We derive a useful correlation between the differential flux and the distribution of particles which can directly offer those best fitting parameters (e.g., the number density N, the thermal characteristic speed and the spectral index ) strongly associated with evaluation of the electromagnetic wave instability. We adopt the assumption of a nearly isotropic pitch-angle distribution (PAD) and the typical LMFIT function in the program IDL to perform a non-linear least squared fitting, and find that the new KT distribution fits well with the observed data during different universal times both in the lower and higher energies. We also carry out the direct comparisons with the generalized Lorentzian (kappa) distribution and find that kappa distribution fits well with observational data at the relatively lower energies but display deviations at higher energies, typically above hundreds of keV. Furthermore, the fitting spectral index basically takes 4, 5 or 6 while the fitting parameters N and are quite different due to different differential fluxes of electrons at different universal times. These results, which are applied to the case of a nearly isotropic PAD, demonstrate that the particle flux satisfies the power-law not only at the lower energies but also at the relativistic energies, and the new KT distribution may present valuable insights into the dynamical features in those space plasmas (e.g., the Earth's outer radiation belts and the inner Jovian magnetosphere) where highly energetic particles exist. Acknowledgments. This work is supported by the National Natural Science Foundation of China grants 40774078, 40774077; the Chinese Academy of Sciences Grant No.KZCX3-SW-144 and the National Key Basic Research Special Foundation of China Grant No. 2006CB806304.

64.	Quanming Lu, B. Lembege, J. B. Tao, and S. Wang, Perpendicular electric field in two-dimensional electron phase-holes: a parameter study, J. Geophys. Res. - Space Phys., 113, A11219, 2008.

63.	Chenglong Shen, Yuming Wang, Pinzhong Ye, and S. Wang, Enhancement of Solar Energetic Particles During A Shock-Magnetic Cloud Interacting Complex Structure, Sol. Phys., 252, 409-418, 2008.

2007 Top

62.	Wang, D. Y, and Quanming Lu, Electron surfing acceleration by electrostatic waves in current sheet, Astrophys. Space Sci., 312, 103-111, 2007.

61.	Wang, D. Y, and Quanming Lu, Electron surfing acceleration in a current sheet by perpendicular electrostatic waves, Adv. Space Res., 39, 1473-1475, 2007.

60.	Chenglong Shen, Yuming Wang, Pinzhong Ye, X. P. Zhao, Bin Gui, and S. Wang, Strength of Coronal Mass Ejection-Driven Shocks Near the Sun, and Its Importance in Predicting Solar Energetic Particle Events, Astrophys. J., 670, 849-856, doi:10.1086/521716, 2007.
Abstract. Coronal shocks are important structures, but there are no direct observations of them in solar and space physics. The strength of shocks plays a key role in shock-related phenomena, such as radio bursts and solar energetic particle (SEP) ´generation. This paper presents an improved method of calculating Alfven speed and shock strength near the Sun. This method is based on using as many observations as possible, rather than one-dimensional global models. Two events, a relatively slow CME on 2001 September 15 and a very fast CME on 2000 June 15, are selected to illustrate the calculation process. The calculation results suggest that the slow CME drove a strong shock, with Mach number of 3.43 4.18, while the fast CME drove a relatively weak shock, with Mach number of 1.90 3.21. This is consistent with the radio observations, which find a stronger and longer decameter-hectometric ( DH ) type II radio burst during the first event, and a short DH type II radio burst during the second event. In particular, the alculation results explain the observational fact that the slow CME produced a major solar energetic particle (SEP) event, while the fast CME did not. Through a comparison of the two events, the importance of shock strength in predicting SEP events is addressed. We acknowledge the use of the data from the LASCO and EIT instruments on board SOHO, the Wind/Waves instrument, the GOES satellites, the ACE/EPAM instrument, and WSO. SOHO is a project of international cooperation between ESA and NASA. We thank Yihua Yan and Shujuan Wang for help in analyzing radio bursts. We are grateful to the referee's comments and suggestions. This work is supported by grants from the NSF of China (40574063, 40525014, 40336052, 40404014), the 973 project (2006CB806304), the Chinese Academy of Sciences (KZCX3-SW-144 and the startup fund), the Program for New Century Excellent Talents in University (NCET-04-0578), and the Ministry of Education (200530).

59.	Yuming Wang and Jie Zhang, A Comparative Study between Eruptive X-class Flares Associated with Coronal Mass Ejections and Confined X-class Flares, Astrophys. J., 665, 1428, 2007.
Abstract. We examine the two kinds of major energetic phenomena that occur in the solar atmosphere: eruptive and confined events. The former describes flares with associated coronal mass ejections (CMEs), while the latter denotes flares without associated CMEs. We find that about 90% of X-class flares are eruptive, but the remaining 10% are confined. To probe why the largest energy releases could be either eruptive or confined, we investigate four X-class events from each of the two types. Both sets of events are selected to have very similar intensities (X1.0 to X3.6) and duration (rise time under 13 minutes and decay time not over 9 minutes) in soft X-ray observations, to reduce any bias due to flare size on CME occurrence. We find that the occurrence of eruption (or confinement) is sensitive to the displacement of the location of the energy release, defined as the distance between the flare site and the flux-weighted magnetic center of the source active region. The displacement is 6 - 17 Mm for confined events but as large as 22 - 37 Mm for eruptive events. This means that confined events occur closer to the magnetic center, while the eruptive events tend to occur close to the edge of active regions. We use the potential field source-surface model to infer the coronal magnetic field above the source active regions and calculate the flux ratio of low (<1.1 Rs) to high (>1.1 Rs) corona. We find that the confined events have a lower ratio (<5.7) than the eruptive events (>7.1). These results imply that a stronger overlying arcade field may prevent energy releases in the low corona from being eruptive, resulting in flares, but without CMEs. We acknowledge the use of the solar data from the LASCO, EIT, and MDI instruments on board the SOHO spacecraft. The SOHO LASCO data used here are produced by a consortium of the Naval Research Laboratory (US), the Max-Planck-Institut fur Aeronomie (Germany), the Laboratoire d'Astronomie (France), and the University of Birmingham (UK). SOHO is a project of international cooperation between ESA and NASA. We also acknowledge the use of the CME catalog generated and maintained at the CDAW Data Center by NASA and the Catholic University of America in cooperation with the Naval Research Laboratory, and the solar event reports compiled by the Space Environment Center of NOAA. We are grateful for useful discussion with X.-P. Zhao at Stanford University, who provided the procedures for the PFSS model. This work is supported by NSF SHINE grant ATM 04-54612 and NASA grant NNG05GG19G. Y. W. is also supported by grants from the National Natural Science Foundation of China (40525014) and the Ministry of Science and Technology (2006CB806304), and J. Z. is also supported by NASA grant NNG04GN36G.

58.	Li, X., Quanming Lu, and B. Li, Ion pickup by finite amplitude parallel propagate Alfven waves, Astrophys. J., 661, L105-L108, 2007.

57.	XIA Qian (夏倩), SHEN Chenglong (申成龙), WANG Yuming (汪毓明), and YE Pinzhong (叶品中), Role of Expansion Velocity of Magnetic Clouds in Flux Rope Model, Chinese J. Space Sci., 27(4), 271-278, 2007.
Abstract. In order to examine the influence of magnetic cloud's expansion on its cylindrical flux rope model, The parameters of MC of 15 typical magnetic clouds with Dst_min < -50 nT during 1998 - 2003 are fitted by applying static and expanding flux rope models, the Multi-MC events and the shock propagation in MC events are not taken into account. It is found that the RMS deviations of the fitting results by the expanding model are all less than or equal to those by the static model, it is better than 30%. That the peak of the magnetic field in MC is at the leading end in the expanding model, it is more consistence with the observations than static model. The inferred expansion speeds of these magnetic clouds are consistent with previous statistical results that the expanding speed of MC is at the order of background Alfven speed. Thus the expanding model matches much more to observed magnetic clouds than the static model. Some differences of the fitted magnetic clouds' parameters between the two models are analyzed. The work is supported by the grants from the National Natural Science Foundation of China (40404014, 40525014), the Ministry of Sciences and Technology of China (973 project 2006CB806304), the Program for New Century Excellent Talents in University (NCET-04-0578), the Chinese Academy of Sciences (startup fund) and National Key Laboratory of Space Weather.

56.	Guo, J., and Quanming Lu, Effetcs of ion-to-electron mass ratio on electron dynamics in collisionless magnetic reconnection, Chinese Phys. Lett., 24, 3199-3202, 2007.

55.	Ming Xiong, Huinan Zheng, S. T. Wu, Yuming Wang, and Shui Wang, Magnetohydrodynamic Simulation of the Interaction between Two Interplanetary Magnetic Clouds and its Consequent Geoeffectiveness, J. Geophys. Res. - Space Phys., 112, A11103, doi:10.1029/2007JA012320, 2007.
Abstract. Numerical studies of the interplanetary ``multiple magnetic clouds (Multi-MC)'' are performed by a 2.5-dimensional ideal magnetohydrodynamic (MHD) model in the heliospheric meridional plane. Both slow MC1 and fast MC2 are initially emerged along the heliospheric equator, one after another with different time intervals. The coupling of two MCs could be considered as the comprehensive interaction between two systems, each comprising of an MC body and its driven shock. The MC2-driven shock and MC2 body are successively involved into interaction with MC1 body. The momentum is transferred from MC2 to MC1. After the passage of MC2-driven shock front, magnetic field lines in MC1 medium previously compressed by MC2-driven shock are prevented from being restored by the MC2 body pushing. MC1 body undergoes the most violent compression from the ambient solar wind ahead, continuous penetration of MC2-driven shock through MC1 body, and persistent pushing of MC2 body at MC1 tail boundary. As the evolution proceeds, the MC1 body suffers from larger and larger compression, and its original vulnerable magnetic elasticity becomes stiffer and stiffer. So there exists a maximum compressibility of Multi-MC when the accumulated elasticity can balance the external compression. This cutoff limit of compressibility mainly decides the maximally available geoeffectiveness of Multi-MC because the geoeffectiveness enhancement of MCs interacting is ascribed to the compression. Particularly, the greatest geoeffectiveness is excited among all combinations of each MC helicity, if magnetic field lines in the interacting region of Multi-MC are all southward. Multi-MC completes its final evolutionary stage when the MC2-driven shock is merged with MC1-driven shock into a stronger compound shock. With respect to Multi-MC geoeffectiveness, the evolution stage is a dominant factor, whereas the collision intensity is a subordinate one. The magnetic elasticity, magnetic helicity of each MC, and compression between each other are the key physical factors for the formation, propagation, evolution, and resulting geoeffectiveness of interplanetary Multi-MC. Acknowledgments. This work was supported by the National Key Basic Research Special Foundation of China (2006CB806304), the Chinese Academy of Sciences grant KZCX3-SW-144, the National Natural Science Foundation of China (40336052, 40404014, 40525014, 40574063, and 40774077), and the Chinese Academy of Sciences (startup fund). S. T. Wu was supported by an NSF grant (ATM03-16115).

54.	Yuming Wang, Chenglong Shen, Pinzhong Ye, and S. Wang, Comparison of Space Weather Effects of Two Major Coronal Mass Ejections in Late 2003, J. Univ. of Sci. & Tech. of China, 37(8), 859-867, 2007.

53.	陈廷娣, 薛向辉, and 窦贤康, 合肥上空钠层夜间激光雷达观测的初步研究, J. Univ. of Sci. & Tech. of China, 37, 873-878, 2007.

52.	Yoon PH,, Wang CB,, and Wu CS, Ring-beam driven maser instability for quasiperpendicular shocks, Phys. Plasmas, 14(2), Art. No. 022901, 2007.

51.	Quanming Lu, and X. Li, Heating of ions by low-frequency Alfven waves, Phys. Plasmas, 14, 042303, 2007.

50.	Guiping Zhou, Jingxiu Wang, Yuming Wang, and Yuzong Zhang, Quasi-simultaneous Flux Emergence in the Events of October/November 2003, Sol. Phys., 244, 13-24, 2007.
Abstract. From late October to the beginning of November 2003, a series of intense solar eruptive events took place on the Sun. More than six active regions (ARs), including three large ARs (NOAA numbers AR 10484, AR 10486, and AR 10488), were involved in the activity. Among the six ARs, four of them bear obviously quasi-simultaneous emergence of magnetic flux. Based on the global Hα and SOHO/EIT EUV observations, we found that a very long filament channel went through the six ARs. This implies that there is a magnetic connection among these ARs. The idea of large-scale magnetic connectivity among the ARs is supported by the consistency of the same chirality in the three major ARs and in their associated magnetic clouds. Although the detailed mechanisms for the quasi-simultaneous flux emergence and the large-scale flux system formation need to be extensively investigated, the observations provide new clues in studying the global solar activity.

49.	Wang, Yuming, Pinzhong Ye, and Shui Wang, The dependence of the geoeffectiveness of interplanetary flux rope on its orientation, with possible application to geomagnetic storm prediction, Sol. Phys., 240, 373-386, 2007.
Abstract. Interplanetary magnetic clouds (MCs) are one of the main sources of large non-recurrent geomagnetic storms. With the aid of a force-free flux rope model, the dependence of the intensity of geomagnetic activity (indicated by $Dst$ index) on the axial orientation (denoted by $theta$ and $phi$ in GSE coordinates) of the magnetic cloud is analyzed theoretically. The distribution of the Dst values in the ($theta$, $phi$) plane is calculated by changing the axial orientation for various cases. It is concluded that (i) geomagnetic storms tend to occur in the region of $theta<0^circ$, especially in the region of $thetalsim-45^circ$, where larger geomagnetic activity could be created; (ii) the intensity of geomagnetic activity varies more strongly with $theta$ than with $phi$; (iii) when the parameters $B_0$ (the magnetic field strength at the flux rope axis), $R_0$ (the radius of the flux rope), or $V$ (the bulk speed) increase, or $\|D\|$ (the shortest distance between the flux rope axis and the $x$-axis in GSE coordinates) decrease, a flux rope not only can increase the intensity of geomagnetic activity, but also is more likely to create a storm, however the variation of $n$ (the density) only has a little effect on the intensity; (iv) the most efficient orientation (MEO) in which a flux rope can cause the largest geomagnetic activity appears at $phisim0^circ$ or $sim180^circ$, and some value of $theta$ which depends mainly on $D$; (v) the minimum $Dst$ value that could be caused by a flux rope is the most sensitive to changes in $B_0$ and $V$ of the flux rope, and for a stronger and/or faster MC, a wider range of the orientation will be geoeffective. Further, through analyzing 20 MC-caused moderate to large geomagnetic storms during 1998 -- 2003, a long-term prediction of MC-caused geomagnetic storms on the basis of the flux rope model is proposed and assessed. The comparison between the theoretical results and the observations shows that there is a close linear correlation between the estimated and observed minimum $Dst$ values. This suggests that using the ideal flux rope to predict practical MC-caused geomagnetic storms is applicable. The possibility of the long-term prediction of MC-caused geomagnetic storms is discussed briefly. We acknowledge the use of the interplanetary magnetic field and solar wind plasma data from the ACE spacecraft and the Dst index from the World Data Center for Geomagnetism at Kyoto University. We thank C. B. Wang for helpful discussion on the Dst model. We also express our thanks to Judy Karpen for partially improving the language of this paper. We thank the anonymous referee for improving the paper in both the scientific content and the language. This work is supported by the grants from the NSF of China (40525014, 40404014, 40336052), the CAS (KZCX3-SW-144 and startup fund), the MOST of China (2006CB806304), and the Program for New Century Excellent Talents in University (NCET-04-0578).

2006 Top

48.	Zhou, Guiping, Yuming Wang, and Jingxiu Wang, Coronal mass ejections associated with polar crown filaments, Adv. Space Res., 38(3), 466-469, 2006.
Abstract. In the sample of 301 well identified earth-directed halo coronal mass ejections (CMEs) from March 1997 to December 2003, all 21 CMEs associated with polar crown filament (PCF) eruptions are analyzed. Here, the PCFs are viewed as the filaments that partially or totally lie along the boundaries of polar coronal holes, with average length over 100000 , and are intrinsically associated with extended bipole regions (EBRs). The current approach focuses on the CME properties and the flux change in the filament channels. According to the magnetic configurations where the PCFs lie, three classes of PCFs are identified. CMEs present distinguishable velocity distributions associated with each type of PCFs. About 28% of these CMEs present geoeffective. Approximately, 1015 Mx SÀ1 magnetic flux inflow into the filament channel and several times of 1020 Mx flux changed during the course of PCF eruption, which are speculated to trigger the PCF eruptions. The work is supported by the National Natural Science Foundation of China (G10243003 and G100233050) and the National Key Basic Science Foundation (TG2000078404).

47.	Yuming Wang, Guiping Zhou, Pinzhong Ye, S. Wang, and Jingxiu Wang, A Study on The Orientation of Interplanetary Magnetic Clouds and Solar Filaments, Astrophys. J., 651, 1245-1255, 2006.
Abstract. Interplanetary magnetic clouds (MCs), a subset of coronal mass ejections (CMEs), are considered to be one of the main sources of geomagnetic storms. Understanding and predicting the magnetic field configuration of MCs by using solar observations, and therefore providing a longer-term prediction of MC-caused geomagnetic storms is an important topic in solar-terrestrial physics and space weather. As a kind of associated eruptive phenomena of CMEs, solar eruptive filaments provide some information in this aspect. Prior to their eruption, the long axis of filaments is thought to be parallel to the axis of surrounding arcade coronal magnetic fields that erupt and develop into interplanetary magnetic clouds. Through investigating three events during August 2000, October 2000 and November 2003, in which the MC and filament were unambiguously associated with the same eruptive solar event, the axial orientations of the MCs are estimated and compared with the filament orientations quantitatively. By defining `tilt angle' as an angle between a pro jected orientation on the plane of the sky and the ecliptic plane, we find that the tilt angle of these MC axes are about 30 , 60 , and 55 , respectively. However, H images show that the associated filaments were all highly curved. The tilt angles of the long axes of these filaments prior to their eruption vary in a range that corresponds to tangents along the entire curved path of the filaments. These ranges are [0 , 75 ], [-15 , 30 ], and [-25 , 110 ], respectively. The comparison between the MCs and filaments shows that for the first and third events, the estimated MC tilt angles are within the ranges of the tilt angles of the associated filaments, and almost parallel to the central parts of the filaments. But for the second event, the MC tilt angle is out of the range suggested by the tilt angle of the filament. This work suggests that (1) the curvature of filaments should be considered in studying the relation between filament and MC's orientation, (2) inconsistencies between MC orientation and filament orientation do occur, even if the curvature of filaments is taken into account, and (3) the largest deviation between the tilt angle of filaments prior to eruption and the tilt angle of associated MCs occurs for those MCs whose estimated axial orientations are not perpendicular to the Earth-Sun line, indicating that the measured part of the MC is not the leading front of the MC. We acknowledge the use of solar data from the LASCO, EIT, and MDI instruments on board the SOHO spacecraft, interplanetary data from the ACE spacecraft, and H images from Kanzelho¨he Solar Observatory, BBSO, and YNAO. SOHO is a project of international cooperation between ESA and NASA. We thank the anonymous referee for many constructive suggestions and criticisms. We also thank Jie Zhang, Arthur I. Poland, and Oscar A. Olmedo for comments and proofreading. This work was supported by grants from the National Natural Science Foundation of China (40525014, 40404014, 40336052, 40336053), the 973 Project (2006CB806304), and the Chinese Academy of Sciences (KZCX3-SW-144 and Startup Fund).

46.	Wang, Yuming, Xianghui Xue, Chenglong Shen, Pinzhong Ye, S. Wang, and Jie Zhang, Impact of major coronal mass ejections on geospace during 2005 September 7 - 13, Astrophys. J., 646, 625-633, 2006.
Abstract. We have analyzed five ma jor CMEs originating from NOAA active region (AR) 808 during the period of September 7 to 13, 2005, when the AR 808 rotated from the east limb to near solar meridian. Several factors that affect the probability of the CMEs' encounter with the Earth are demonstrated. The solar and interplanetary observations suggest that the 2nd and 3rd CMEs, originating from E 67 and E 47 respectively, encountered the Earth, while the 1st CME originating from E 77 missed the Earth, and the last two CMEs, although originating from E 39 and E 10 respectively, probably only grazed the Earth. Based on our ice-cream cone model (Xue et al. 2005) and CME deflection model (Wang et al. 2004), we find that the CME span angle and deflection are important for the probability of encountering Earth. The large span angles allowed the middle two CMEs hit the Earth, though their source locations were not close to the solar central meridian. The significant deflection made the first CME totally miss the Earth though it also had wide span angle. The deflection may also have made the last CME nearly miss the Earth though it originated close to the disk center. We suggest that, in order to effectively predict whether a CME will encounter the Earth, the factors of the CME source location, the span angle, and the interplanetary deflection should all be taken into account. We acknowledge the use of the solar data from the LASCO and MDI instruments on board SOHO spacecraft and from the MK4 coronameter at Mauna Loa Solar observatory, and the interplanetary data from Wind spacecraft.We also acknowledge the use of solar event reports compiled by the Space Environment Center of NOAA. We thank Michael L. Kaiser for the comment on type II radio bursts, and thank Ian Richardson and Daniel Berdichevsky for comments on the interplanetary solar wind observations. SOHO is a project of international cooperation between ESA and NASA. This work is supported by the National Natural Science Foundation of China (40525014, 40404014, 40336052, 40336053), the Chinese Academy of Sciences (KZCX3-SW-144 and startup fund), and the Program for New Century Excellent Talents in University (NCET-04-0578).

45.	Shen, Chenglong, Yuming Wang, Pinzhong Ye, and S. Wang, Is There Any Evident Effect of Coronal Holes on Gradual Solar Energetic Particle Events?, Astrophys. J., 639, 510-515, 2006.
Abstract. Gradual solar energetic particle (SEP) events are thought to be produced by shocks, which are usually driven by fast coronal mass ejections (CMEs). The strength and magnetic field configuration of the shock are considered the two most important factors for shock acceleration. Theoretically, both of these factors should be unfavorable for producing SEPs in or near coronal holes (CHs). Meanwhile, CMEs and CHs could impact each other. Thus, to answer the question whether CHs have real effects on the intensities of SEP events produced by CMEs, a statistical study is performed. First, a brightness gradient method is developed to determine CH boundaries. Using this method, CHs can be well identified, eliminating any personal bias. Then 56 front-side fast halo CMEs originating from the western hemisphere during 1997 2003 are investigated as well as their associated large CHs. It is found that neither CH proximity nor CH relative location manifests any evident effect on the proton peak fluxes of SEP events. The analysis reveals that almost all of the statistical results are significant at no more than one standard deviation. Our results are consistent with the previous conclusion suggested by Kahler that SEP events can be produced in fast solar wind regions and there is no requirement for those associated CMEs to be significantly faster. We acknowledge the use of the data from the SOHO, Yohkoh, and GOES spacecraft and the CH maps from the Kitt Peak Observatory.We express our heartfelt thanks to the anonymous referee for constructive suggestions and criticisms. SOHO is a project of international cooperation between ESA and NASA. This work is supported by the Chinese Academy of Sciences (KZCX3-SW-144 and startup fund), the National Natural Science Foundation of China (40336052, 40574063, 40404014), and the Program for New Century Excellent Talents in University (NCET-04-0578).

44.	Quanming Lu, C. S. Wu, and S. Wang, The nearly isotropic velocity distributions of energetic electrons in the solar wind, Astrophys. J., 638, 1169-1175, 2006.

43.	Shen, Cheng-Long, Yu-Ming Wang, Pin-Zhong Ye, and Shui Wang, Analysis of typical events of coronal holes against the formation of solar energetic particle events, Chinese J. Geophys., 49(3), 629-635, 2006.
Abstract. By comparing and analyzing the solar and interplanetary data of two fast halo coronal mass ejections (CMEs), we find that the CME far away from coronal holes (CHs) caused a great solar energetic particle (SEP) events, but the other one very close to CHs did not cause a major SEP events. It implies that coronal holes might suppress the production of SEPs. Further, by investigating all fast halo CMEs within a distance of 0.2 $R_s$ from CHs during 1997 -- 2003, it is found that none of the CMEs produced a major SEP event. The result proves that the CHs may have effects against the CME producing SEPs. The possible reasons why CHs may prevent CMEs from producing SEPs are briefly addressed finally. We acknowledge the use of the data from the SOHO, Yohkoh, ACE and GOES spacecraft, and the CH maps from the Kitt Peak Observatory. SOHO is a project of international cooperation between ESA and NASA. This work is supported by the National Natural Science Foundation of China (40525014, 40574063, 40404014, 40336052), the Chinese Academy of Sciences (KZCX3-SW-144 and startup fund), the program for New Century Excellent Talents in University (NCET-04-0578), and the open research program of Key Laboratory for Space Weather, Chinese Academy of Sciences.

42.	Zheng HN,, Zhang YY,, Wang S,, Wang CB,, and Li Y, Propagation of fast magnetoacoustic waves in stratified solar atmosphere, Chinese Phys. Lett., 23 (2):, 399-402, 2006.

41.	Xianghui Xue, Weixing Wan, Jiangang,Xiong, and Xiankang Dou, Diurnal tides in mesosphere/low-thermosphere (MLT) during 2002 at Wuhan using Canonical Correlation Analysis, J. Geophys. Res. - Space Phys., 112, doi:10.1029/2006JD007490, 2006.

40.	M. Xiong, H. N. Zheng, Yuming Wang, and S. Wang, Magnetohydrodynamic simulation of the interaction between interplanetary strong shock and magnetic cloud and its consequent geoeffectiveness, J. Geophys. Res. - Space Phys., 111, A08105, doi:10.1029/2005JA011593, 2006.
Abstract. Numerical studies have been performed to interpret the observed ``shock overtaking magnetic cloud (MC)" event by a 2.5 dimensional magnetohydrodynamic (MHD) model in the heliospheric meridional plane. Results of an individual MC simulation show that the MC travels with a constant bulk flow speed. The MC is injected with a very strong inherent magnetic field over that in the ambient flow and expands rapidly in size initially. Consequently, the diameter of the MC increases in an asymptotic speed while its angular width contracts gradually. Meanwhile, simulations of MC-shock interaction are also presented, in which both a typical MC and a strong fast shock emerge from the inner boundary and propagate along the heliospheric equator, separated by an appropriate interval. The results show that the shock first catches up with the preceding MC, then penetrates through the MC, and finally merges with the MC-driven shock into a stronger compound shock. The morphologies of shock front in interplanetary space and MC body behave as a central concave and a smooth arc, respectively. The compression and rotation of the magnetic field serve as an efficient mechanism to cause a large geomagnetic storm. The MC is highly compressed by the overtaking shock. Contrarily, the transport time of the incidental shock influenced by the MC depends on the interval between their commencements. Maximum geoeffectiveness results from when the shock enters the core of preceding MC, which is also substantiated to some extent by a corresponding simplified analytic model. Quantified by the Dst index, the specific result is that the geoeffectiveness of an individual MC is largely enhanced with 80% increment in maximum by an incidental shock. This work was supported by the National Natural Science Foundation of China (40274050, 40404014, 40336052 and 40525014), and the Chinese Academy of Sciences (startup fund). M. Xiong was also supported by Innovative Fund of University of Science and Technology of China for Graduate Students (KD2005030).

39.	Xiong, Ming, Huinan Zheng, Yuming Wang, and Shui Wang, Magnetohydrodynamic Simulation of the Interaction between Interplanetary Strong Shock and Magnetic Cloud and its Consequent Geoeffectiveness 2: Oblique Collision, J. Geophys. Res. - Space Phys., 111, A11102, doi:10.1029/2006JA011901, 2006.
Abstract. Numerical studies of the interplanetary "shock overtaking magnetic cloud (MC)" event are continued by a 2.5 dimensional magnetohydrodynamic (MHD) model in heliospheric meridional plane. Interplanetary direct collision (DC)/oblique collision (OC) between an MC and a shock results from their same/different initial propagation orientations. For radially erupted MC and shock in solar corona, the orientations are only determined respectively by their heliographic locations. OC is investigated in contrast with the results in DC [Xiong et al., 2006]. The shock front behaves as a smooth arc. The cannibalized part of MC is highly compressed by the shock front along its normal. As the shock propagates gradually into the preceding MC body, the most violent interaction is transferred sideways with an accompanying significant narrowing of the MC's angular width. The opposite deflections of MC body and shock aphelion in OC occur simultaneously through the process of the shock penetrating the MC. After the shock\'s passage, the MC is restored to its oblate morphology. With the decrease of MC-shock commencement interval, the shock front at 1 AU traverses MC body and is responsible for the same change trend of the latitude of the greatest geoeffectiveness of MC-shock compound. Regardless of shock orientation, shock penetration location regarding the maximum geoeffectiveness is right at MC core on the condition of very strong shock intensity. An appropriate angular difference between the initial eruption of an MC and an overtaking shock leads to the maximum deflection of the MC body. The larger the shock intensity is, the greater is the deflection angle. The interaction of MCs with other disturbances could be a cause of deflected propagation of interplanetary coronal mass ejection (ICME). This work was supported by the National Natural Science Foundation of China (40336052, 40404014, 40525014, and 40574063), the Chinese Academy of Sciences (startup fund), and the National Key Basic Research Special Foundation of China(2006CB806304). M. Xiong was also supported by Innovative Fund of University of Science and Technology of China for Graduate Students (KD2005030).

38.	Quanming Lu., L. D. Xia, and S. Wang, Hybrid simulations of parallel and oblique electromagnetic alpha/proton instabilities in the solar wind, J. Geophys. Res. - Space Phys., 111, A09101, 2006.

37.	Quanming Lu, F. Guo, and S. Wang, Magnetic spectral signatures in the terrestrial plasma depletion layer:hybrid simulations, J. Geophys. Res. - Space Phys., 111, 04207, 2006.

36.	Quanming Lu, and S. Wang, Electromagnetic waves downstream of quasi-perpendicular shocks, J. Geophys. Res. - Space Phys., 111, A05204, 2006.

35.	X. R. Fu, Quanming Lu, and S. Wang, The process of electron acceleration during collisionless magnetic, Phys. Plasmas, 13, 012309, 2006.

34.	Wang CB,, Wu CS,, and Yoon PH, Heating of ions by Alfven waves via nonresonant interactions, Phys. Rev. Lett., 96 (12):, Art. No. 125001, 2006.

33.	Wu, C. S., C. B. Wang, and Quanming Lu, Density depletion in coronal flux tube associated with solar radio emission, Sol. Phys., 235, 317-329, 2006.

2005 Top

32.	Chen YP,, Wang CB,, and Zhou GC, Maser instability driven by an electron beam with losscone-beam distribution, ACTA PHYSICA SINICA, 54 (7):, 3221-3227, 2005.

31.	Wang, Y., H. Zheng, S. Wang, and P. Ye, MHD simulation of the formation and propagation of multiple magnetic clouds in the heliosphere, Astron. & Astrophys., 434, 309-316, 2005. (Figure 2 is adopted as the cover page.)
Abstract. A multiple-magnetic-cloud (Multi-MC) structure formed by the overtaking of two successive coronal mass ejections (CMEs) in the heliosphere is studied by using a 2.5-D MHD simulation. This simulation illustrates the process of the formation and propagation of two identical CMEs, which are ejected with speeds of 400 km s−1 and 600 km s−1 respectively and initially separated by 12 h. The results show that it takes ∼18 h for the fast cloud to catch up with the preceding slow one, then the two clouds form a Multi-MC structure that arrives at 1 AU three days later. The fast cloud is slowed down significantly because of the blocking by the preceding slow one. This implies that the travel time of a Multi-MC structure is dominated by the preceding slow cloud. Moreover, most primary observational characteristics of Multi-MC at 1 AU are well represented by the simulation. In addition, by combining observations, theoretical model and the simulation results, differences between Multi-MC and other types of in-situ observed double-flux-rope structure are addressed. A comparison of Multi-MC to coronalmass-ejection cannibalization near Sun is also given. We acknowledge the use of the data from ACE spacecraft. We also express our thanks to the referee for his constructive suggestions. This work is supported by the Chinese Academy of Sciences (KZCX2-SW-136), the National Natural Science Foundation of China (40404014, 40336052, 40336053 and 40274050), and the State Ministry of Science and Technology of China (G2000078405).

30.	Wu CS,, Wang CB,, Zhou GC,, and et al., Altitude-dependent emission of type III solar radio bursts, Astrophys. J., 621 (2):, 1129-1136 Part 1, 2005.

29.	Quanming Lu, and S. Wang, Proton and He2+ Temperature Anisotropies in the Solar wind driven by ion cyclotron waves, Chinese J. Astron. & Astrophys., 5(2), 184-192, 2005.

28.	熊明(Xiong, Ming), 郑惠南(Hui-Nan Zheng), 汪毓明(Yu-Ming Wang), 傅向荣(Xiang-Rong Fu), 王水(Shui Wang), and 窦贤康(Xian-Kang Dou), A numerical simulation on the solar-terrestrial transit time of successive CMEs during 4-5 November 1998, Chinese J. Geophys., 48(4), 805-813, 2005.
Abstract. The solar-terrestrial transit process of three successive coronal mass ejections (CMEs) during November 45, 1998 has been investigated numerically in one-dimensional spherical geometry. These CMEs interact with each other while they are propagating in interplanetary space and finally form a “Complex Ejecta”. A Harten’s total variation diminishing (TVD) scheme is applied to solve magnetohydrodynamic (MHD) equations numerically, starting from an ambient solar wind equilibrium, with appropriate dimensionless gravity parameter , plasma beta , and gas polytropic index. The equilibrium is consistent in solar wind speed vr, proton number density Np, and the ratio of proton thermal pressure to magnetic pressure p with the observation of ACE spacecraft at Lagrange point (L1). Merely velocity pulse is introduced in the numerical computation, whose amplitude and duration are determined by observation data of Lasco/C2, GOES, LEAR combined with CME’s “Cone Model” proposed by Michalek et al. The results show that the differences of two shock arrival times (SATs)between the numerical calculation and ACE observation are 3 and 4 hours respectively. Therefore the numerical model proposed in this paper can estimate SAT and rough shock intensity formed by successive CMEs evolving in interplanetary space and suggests a potential application in SAT prediction for space weather. This work was supported by the National Natural Science Foundation of China (40274050, 40336052, 40404014), the Ministry of Science and Technology of China (NKBRSF G2000078405) and the Chinese Academy of Sciences (KZCX2-SW-136). The authors also acknowledge the use of observation data from SOHO, ACE, GOES spacecrafts and LEAR observatory with gratitude.

27.	Quanming Lu, and S. Wang, Formation of He2+ shell-like distributions downstream of the Earth's bow shock, Geophys. Res. Lett., 32, L03111, 2005.

26.	Wang, Yuming, Guiping Zhou, Pinzhong Ye, S. Wang, and Jingxiu Wang, Orientation and geoeffectiveness of magnetic clouds as consequences of filament eruptions, in Coronal and Stellar Mass Ejections, Proceedings of IAU symposium No. 226, , edited by K. P. Dere, J. Wang, and Y. Yan, p. 448-453, (Beijing, China, September 13-17, 2004), 2005.
Abstract. We acknowledge the use of the data from the SOHO, Trace and ACE spacecraft. This work is supported by the Chinese Academy of Sciences (KZCX2-SW-136), the National Natural Science Foundation of China (40404014, 40336052, 40336053), and the State Ministry of Science and Technology of China (G2000078405).

25.	Quanming Lu, D. Y. Wang, and S. Wang, Generation mechanism of electrostatic solitary structures in the Earth’s auroral region, J. Geophys. Res. - Space Phys., 110, A03223, 2005.

24.	X. H. Xue, C. B. Wang, and X. K. Dou, An ice-cream cone model for coronal mass ejections, J. Geophys. Res. - Space Phys., 110, A08103, doi:10.1029/2004JA010698, 2005.

23.	WANG, Yu-Ming and Shui WANG, Comprehensive Studies on Magnetic Clouds in Interplanetary Space and Their Associated Events, J. Grad. School of CAS, 22(2), 248-254, 2005.
Abstract. The relationships between the coronal mass ejections (CMEs), interplanetary disturbances and geomagnetic storms are studied, involving the solar source distribution of geoeffective halo CMEs, periodicity of CMEs, X-ray flares, geomagnetic disturbances, threshold of interplanetary parameters in causing geomagnetic storms, etc. As a kind of interplanetary complex structure, multiple magnetic clouds (Multi-MCs) are proposed for the first time, which probably has strong geoeffectiveness. Based on the observations, some primary characteristics of Multi-MCs are summarized. Moreover, the phonomenon of a shock advancing into a preceding magnetic cloud has been investigated as well as its potential geoeffectiveness. A simple theoretical model is developed to estimate the intensity of geomagnetic storms when a shock is entering a preceding cloud. Supported by National Natural Science Foundation of China (49834030, 40336053), the State Ministry of Science and Technology of China (G2000078405) and the Chinese Academy of Sciences (CKZCX2-SW-136)

22.	Xue, X. H., Yuming Wang, P. Z. Ye, S. Wang, and M. Xiong, Analysis on the interplanetary causes of the great magnetic storms in solar maximum (2000-2001), Planet. & Space Sci., 53, 443-457, 2005.
Abstract.

21.	Wang, Yuming, Pinzhong Ye, Guiping Zhou, Shujuan Wang, S. Wang, Yihua Yan, and Jingxiu Wang, The interplanetary responses to the great solar activities in late October 2003, Sol. Phys., 226, 337-357, 2005.
Abstract.

20.	Wang, Yuming, Chenglong Shen, Pinzhong Ye, and S. Wang, Effect of coronal holes on gradual solar energetic particle events, Proceedings of Solar Wind 11/SOHO 16, EAS SP PUBL 592, 461-464 (Whistler, Canada, June 12-17), 2005.

2004 Top

19.	Wang, Y.-M., P.-Z. Ye, and S. Wang, An interplanetary origin of great geomagnetic storms: Multiple magnetic clouds, Chinese J. Geophys., 47(3), 369-375, 2004.

18.	Guo, Jun, Quan-Ming Lu, Shui Wang, Yu-Ming Wang, and Xian-Kang Dou, Whistler mode waves in collisionless magnetic reconnection, Chinese Phys. Lett., 21(7), 1306-1309, 2004.

17.	Quanming Lu, L. Q. Wang, Y. Zhou, and S. Wang, Electromagnetic instabilities excited by electron temperature anisotropy, Chinese Phys. Lett., 21, 129-132, 2004.

16.	Wang, D. Y., G. L. Huang, and Quanming Lu, Effect of electron drift velocity on whistler instability in collisionless magnetic reconnection, Chinese Phys. Lett., 21, 1997-2000, 2004.

15.	Quanming Lu, and S. Wang, , Phys. Plasmas, 11(1), 80-89, 2004.

14.	Wang, Yuming, Chenglong Shen, S. Wang, and Pinzhong Ye, Deflection of coronal mass ejection in the interplanetary medium, Sol. Phys., 222, 329-343, 2004.
Abstract. A solar coronal mass ejection (CME) is a large-scale eruption of plasma and magnetic fields from the Sun. It is believed to be the main source of strong interplanetary disturbances that may cause intense geomagnetic storms. However, not all front-side halo CMEs can encounter the Earth and produce geomagnetic storms. The longitude distribution of the Earth-encountered front-side halo CMEs (EFHCMEs) has not only an eastwest (EW) asymmetry (Wang et al., 2002), but also depends on the EFHCMEs' transit speeds from the Sun to 1 AU. The faster the EFHCMEs are, the more westward does their distribution shift, and as a whole, the distribution shifts to the west. Combining the observational results and a simple kinetic analysis, we believe that such EW asymmetry appearing in the source longitude distribution is due to the deflection of CMEs' propagation in the interplanetary medium. Under the effect of the Parker spiral magnetic field, a fast CME will be blocked by the background solar wind ahead and deflected to the east, whereas a slow CME will be pushed by the following background solar wind and deflected to the west. The deflection angle may be estimated according to the CMEs' transit speed by using a kinetic model. It is shown that slow CMEs can be deflected more easily than fast ones. This is consistent with the observational results obtained by Zhang et al. (2003), that all four Earth-encountered limb CMEs originated from the east. On the other hand, since the most of the EFHCMEs are fast events, the range of the longitude distribution given by the theoretical model is E40 ,W70 , which is well consistent with the observational results (E 40 , W 75 ). We acknowledge the use of the data from the SOHO, Yohkoh, GOES, ACE and Wind spacecraft. This work is supported by the Chinese Academy of Sciences (KZCX2-SW-136), the National Natural Science Foundation of China (40336052, 40336053), and the State Ministry of Science and Technology of China (G2000078405).

2003 Top

13.	Quanming Lu, V. Getov, and S. Wang, Using Java for plasma PIC simulations, Proceedings of the International Parallel and Distributed Processing Symposium (IPDPS'03), , 137-143, 2003.

12.	Quanming Lu, and V. Getov, Mixed-language high-performance computing for plasma simulations, Scientific Programming, 11, 57-66, 2003.

11.	叶品中(Ye, Pin-Zhong) and 汪毓明(Yu-Ming Wang), A study on the Bs events in interplanetary space and the associated CMEs in 2000 (Chinese version), Chinese J. Space Sci., 23, 7-17, 2003.

10.	汪毓明(Wang, Yuming), 叶品中(Pinzhong Ye), and 王水(Shui Wang), Magnetic cloud in interplanetary space (Chinese version), Progress in Astron., 21(4), 301-317, 2003.

9.	Wang, Yuming, C. L. Shen, S. Wang, and P. Z. Ye, An empirical formula relating the geomagnetic storm's intensity to the interplanetary parameters: -VBz and Δt, Geophys. Res. Lett., 30(20), 2039, doi:10.1029/2003GL017901, 2003.
Abstract. We statistically study 105 geomagnetic storms with aDst peak value À50 nT during 1998 2001 to examin the influence of the interplanetary parameters ÀVBz and its duration Át on the intensity of geomagnetic storms. About 33% of the events are associated with intense storms with Dstmin À100 nT. It is found that ÀVBz is much more important than Át for the formation of geomagnetic storms. A stronger ÀVBz can produce a more intense storm, whereas a longer Át can not. A simple empirical formula relating the Dst peak value to ÀVBz and Át is obtained, which shows a good correlation (CC = 0.9528) between the estimate value and the observations. This formula suggests that a compressed Bs field tends to have a more prominent geoeffectiveness. Moreover, we also identify 33 large ÀVBz intervals with ÀVBz > 5 mV/m and Át > 3 hours in the same study interval, and find that they all caused intense storms (Dstmin À100 nT) and 8/9 of the great storms (Dstmin À200 nT) were due to interplanetary compressed structures. We acknowledge the use of the data from the ACE and WIND spacecraft and the Dst index from World Data Center. We thank the anonymous referees for the constructive comments. This work is supported by the National Natural Science Foundation of China (49834030), the State Ministry of Science and Technology of China (G2000078405), and the Chinese Academy of Sciences (KZCX2-SW-136).

8.	Wang, Y. M., P. Z. Ye, S. Wang, and X. H. Xue, An interplanetary cause of large geomagnetic storms: Fast forward shock overtaking preceding magnetic cloud, Geophys. Res. Lett., 30(13), 1700, doi:10.1029/2002GL016861, 2003.
Abstract. In the event that occurred during October 3 6, 200 at least one magnetosonic wave and one fast forward shock advanced into the preceding magnetic cloud (MC). By using the field and plasma data from the ACE and WIND spacecraft, we analyze the evolution of this event, including the characteristics and changes of the magnetic fields and plasma. At the rear part of the cloud, a large southward magnetic field is caused by a shock compression. The shock intensified a preexisting southward magnetic field. This increased the geoeffectiveness of this event and produced an intense geomagnetic storm with Dst = À175 nT. We also describe another event with a shock overtaking a MC on Nov. 6, 2001. A great geomagnetic storm of intensity Dst = 292 nT resulted. These observations are used to argue that shock compression of magnetic cloud fields is an important interplanetary cause of large geomagnetic storms. Our analyses suggest that the geoeffectiveness is related to the direction of preexisting magnetic fields, the intensity of overtaking shock, and the amount of shock penetration into the preceding MC. We acknowledge the use of the data from ACE, WIND spacecraft and the Dst index from World Data Center. We thank the anonymous referee very much for the constructive comments and criticisms. This work is supported by the National Natural Science Foundation of China (49834030), the State Ministry of Science and Technology of China (G2000078405), and the Chinese Academy of Sciences (KZCX2-SW-136).

7.	Wang, Y. M., P. Z. Ye, and S. Wang, Multiple magnetic clouds: Several examples during March - April, 2001, J. Geophys. Res. - Space Phys., 108(A10), 1370, doi:10.1029/2003JA009850, 2003.
Abstract. Multiple magnetic cloud (Multi-MC), which is formed by the overtaking of successive coronal mass ejections (CMEs), is a kind of complex structure in interplanetary space. Multi-MC is worthy of notice due to its special properties and potential geoeffectiveness. Using the data from the ACE spacecraft, we identify the three cases of Multi-MC in the period from March to April 2001. Some observational signatures of Multi-MC are concluded: (1) Multi-MC only consists of several magnetic clouds and interacting regions between them; (2) each subcloud in Multi-MC is primarily satisfied with the criteria of isolated magnetic cloud, except that the proton temperature is not as low as that in typical magnetic cloud due to the compression between the subclouds; (3) the speed of solar wind at the rear part of the front subcloud does not continuously decrease, rather increases because of the overtaking of the following subcloud; (4) inside the interacting region between the subclouds, the magnetic field becomes less regular and its strength decreases obviously, and (5) b value increases to a high level in the interacting region. We find out that two of three Multi-MCs are associated with the great geomagnetic storms (Dst À200 nT), which indicate a close relationship between the Multi-MCs and some intense geomagnetic storms. The observational results imply that theMulti-MC is possibly another type of the interplanetary origin of the large geomagnetic storm, though not all of them have geoeffectiveness. Based on the observations from Solar and Heliospheric Observatory (SOHO) and GOES, the solar sources (CMEs) of these Multi-MCs are identified. We suggest that such successive halo CMEs are not required to be originated from a single solar region. Furthermore, the relationship between Multi-MC and complex ejecta is analyzed, and some similarities and differences between them are discussed. Acknowledgments. We acknowledge the use of the data from ACE, SOHO, GOES spacecraft, and the Dst index from World Data Center. We thank the anonymous referees for the constructive comments. This work is supported by the National Natural Science Foundation of China (49834030), the State Ministry of Science and Technology of China (G2000078405), and the Chinese Academy of Sciences (KZCX2-SW-136).

6.	Wang CB,, Chao JK,, and Lin CH, Influence of the solar wind dynamic pressure on the decay and injection of the ring current, J. Geophys. Res. - Space Phys., 108 (A9):, Art. No. 1341, 2003.

5.	Wang CB, and Chao JK, Comment on "Effects of fast and slow solar wind on the correlation between interplanetary medium and geomagnetic activity" by P. Ballatore, J. Geophys. Res. - Space Phys., 108 (A10):, Art. No. 1386, 2003.

4.	Lou, Y.-Q., Y.-M. Wang, Z. Fan, S. Wang, and J. Wang, Periodicities in solar coronal mass ejections, Mon. Not. R. Astron. Soc., 345, 809-818, 2003.
Abstract. Mid-term quasi-periodicities in solar coronal mass ejections (CMEs) during the most recent solar maximum cycle 23 are reported here for the first time using the four year data (February 5, 1999 to February 10, 2003) of the Large Angle Spectrometric Coronagraph (LASCO) onboard the Solar and Heliospheric Observatory (SOHO). In parallel, mid-term quasi-periodicities in solar X-ray flares (class > M5.0) from the Geosynchronous Operational Environment Satellites (GOES) and in daily averages of Ap index for geomagnetic disturbances from the World Data Center (WDC) at the International Association for Geomagnetism and Aeronomy (IAGA) are also examined for the same four-year time span. By Fourier power spectral analyses, the CME data appears to contain significant power peaks at periods of ~ 358 +/- 38, ~ 272 +/- 26, ~ 196+/-13 days and so forth, while except for the ~ 259+/-24-day period, X-ray solar flares of class > M5.0 show the familiar Rieger-type quasi-periods at ~ 157 +/- 11, ~ 122 +/- 5, ~ 98 +/- 3 days and shorter ones until ~ 34 +/- 0:5 days. In the data of daily averages of Ap index, the two significant peaks at periods ~ 273 +/- 26 and ~ 187 +/- 12 days (the latter is most prominent) could imply that CMEs (periods at ~ 272+/-26 and ~ 196 +/- 13 days) may be proportionally correlated with quasi-periodic geomagnetic storm disturbances; at the speculative level, the ~ 138 +/- 6-day period might imply that X-ray flares of class > M5.0 (period at ~ 157+/-11 days) may drive certain types of geomagnetic disturbances; and the ~ 28 +/- 0.2-day periodicity is most likely caused by recurrent high-speed solar winds at the Earth’s magnetosphere. For the same three data sets, we further perform Morlet wavelet analysis to derive period-time contours and identify wavelet power peaks and timescales at the 99 percent confidence level for comparisons. Several conceptual aspects of possible equatorially trapped Rossby-type waves at and beneath the solar photosphere are discussed. This research (Y.Q.L.) was supported in part by grants from US NSF (AST-9731623) to the University of Chicago, by the ASCI Center for Astrophysical Thermonuclear Flashes at the University of Chicago under Department of Energy contract B341495, by the Special Funds for Major State Basic Science Research Projects of China, by the Collaborative Research Fund from the NSF of China for Outstanding Young Overseas Chinese Scholars (NSFC 10028306) at the National Astronomical Observatories, Chinese Academy of Sciences, and by the Yangtze Endowment from the Ministry of Education through the Tsinghua University. Affliated institutions of Y.Q.L share this contribution. Z.H.F. was supported in part by the NSFC grant 10243006 and the Ministry of Science and Technology of China under grant TG1999075401.

3.	Quanming Lu, Thermodynamic evolution of phase explosion during high-power nanosecond laser ablation, Phys. Rev. E, 67, 016410, 2003.

2.	Wang, Y. M., P. Z. Ye, S. Wang, and M. Xiong, Theoretical analysis on the geoeffectiveness of a shock overtaking a preceding magnetic cloud, Sol. Phys., 216, 295-310, 2003.
Abstract. The shock compression of the preexisting southward directed magnetic field can enhance a geomagnetic disturbance. A simple theoretical model is proposed to study the geoeffectiveness of a shock overtaking a preceding magnetic cloud. Our aim is to answer theoretically the question how deep the shock enters into the cloud when the event just reaches the maximum geoeffectiveness. The results suggest that the minimum value of Dst decreases initially, then increases again while the shock propagates from the border to the center of the cloud. There is a position where the shock compression of the preceding cloud obtains the maximum geoeffectiveness. In different situations, the position is different. The higher the overtaking shock speed is, the deeper is this position, and the smaller is the corresponding Dstmin . Some shortcomings of this theoretical model are also discussed. We acknowledge the use of the data from ACE and WIND spacecraft and the Dst index from World Data Center. This work is supported by the National Natural Science Foundation of China (49834030), the State Ministry of Science and Technology of China (G2000078405), and the Chinese Academy of Sciences (KZCX2-SW-136).

1.	Wang, J., G. Zhou, Y. Wang, and L. Song, Circular polarization in a solar filament, Sol. Phys., 216, 143-157, 2003.

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