Japan Geoscience Union Meeting 2019

Session information

[E] Oral

P (Space and Planetary Sciences ) » P-EM Solar-Terrestrial Sciences, Space Electromagnetism & Space Environment

[P-EM13] Inner magnetosphere: Recent understanding and new insights

Tue. May 28, 2019 1:45 PM - 3:15 PM A04 (TOKYO BAY MAKUHARI HALL)

convener:Yusuke Ebihara(Research Institute for Sustainable Humanosphere, Kyoto University), Danny Summers(Memorial University of Newfoundland), Yoshizumi Miyoshi(Institute for Space-Earth Environmental Research, Nagoya University), Shinji Saito(Graduate School of Science, Nagoya University), Chairperson:Danny Summers, Yoshizumi Miyoshi(ISEE, Nagoya University)

The inner magnetosphere is characterized by the dominance of intrinsic dipolar Earth's magnetic field. The dipolar magnetic field traps charged particles, resulting in the formation of unique particle environment known as the plasmasphere, the ring current, and the radiation belt. The inner magnetosphere is always changing because of incoming energy from the outer magnetosphere and the ionosphere in the forms of particles and electromagnetic fields. In the inner magnetosphere, the particle energy is transferred to the field energy, and vice versa. The mutual coupling between particles and fields also makes the inner magnetosphere unique. The outgoing energy to these regions is also known to be significant, such as precipitation into the upper atmosphere and sub-auroral disturbances. A number of satellites (e.g., DMSP, NOAA, Geotail, Cluster, THEMIS, Van Allen Probes, MMS, and Arase), ground-based instruments (e.g., SuperDARN and EISCAT radars, magnetometers, and cameras), and numerical simulations (e.g., global particle simulation, PIC simulation, and hybrid simulation) have successfully surveyed the inner magnetosphere, which deepen our knowledge significantly. USAF DSX, UCLA Elfin and NASA CeRES will be launched soon, being expected to provide important information. We solicit papers describing recent results on the inner magnetosphere and/or its coupling with the other regions, including the ionosphere and the outer magnetosphere.

2:40 PM - 2:55 PM

*Aaron T. Hendry1, Ondrej Santolik1,2, Yoshizumi Miyoshi3, Yoshiya Kasahara4, Yasumasa Kasaba5, Ayako Matsuoka6, Craig J Rodger7, Mark Clilverd8, Masafumi Shoji3, Shoya Matsuda6, Craig Kletzing9, Iku Shinohara6 (1.Dept. of Space Physics, Inst. of Atmospheric Physics, Czech Acad. of Science, 2.Fac. of Mathematics and Physics, Charles Univ., 3.Inst. for Space Earth Environmental Research, Nagoya Univ., 4.Graduate School of Natural Science and Technology, Kanazawa Univ., 5.Planetary Plasma and Atmospheric Research Center, Tohoku Univ., 6.Inst. of Space and Astronautical Science, Japan Aerospace Exploration Agency, 7.Dept. of Physics, Univ. of Otago, 8.British Antarctic Survey (NERC), 9.Dept. of Physics and Astronomy, Univ. of Iowa)

2:55 PM - 3:10 PM

*Keisuke Hosokawa1, Yoshizumi Miyoshi2, Shin-ichiro Oyama2, Yasunobu Ogawa3, Satoshi Kurita2, Yoshiya Kasahara4, Mitsunori Ozaki4, Yasumasa Kasaba5, Satoshi Yagitani4, Shoya Matsuda6, Fuminori Tsuchiya5, Atsushi Kumamoto5, Iku Shinohara6, Ryoichi Fujii7 (1.Department of Communication Engineering and Informatics, University of Electro-Communications, 2.ISEE, Nagoya University, 3.National Institute of Polar Research, 4.Kanazawa University, 5.Tohoku University, 6.ISAS/JAXA, 7.Research Organization of Information and Systems)

Discussion (3:10 PM - 3:15 PM)

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