日本地球惑星科学連合2014年大会

講演情報

インターナショナルセッション(口頭発表)

セッション記号 P (宇宙惑星科学) » P-EM 太陽地球系科学・宇宙電磁気学・宇宙環境

[P-EM08_2AM2] Space Weather and Space Climate

2014年5月2日(金) 10:55 〜 12:45 411 (4F)

コンビーナ:*片岡 龍峰(国立極地研究所)、海老原 祐輔(京都大学生存圏研究所)、草野 完也(名古屋大学太陽地球環境研究所)、清水 敏文(宇宙航空研究開発機構宇宙科学研究所)、三好 由純(名古屋大学太陽地球環境研究所)、浅井 歩(京都大学宇宙総合学研究ユニット)、佐藤 達彦(日本原子力研究開発機構)、陣 英克(情報通信研究機構)、伊藤 公紀(横浜国立大学大学院工学研究院)、宮原 ひろ子(武蔵野美術大学造形学部)、座長:陣 英克(情報通信研究機構)

11:30 〜 11:45

[PEM08-17] プラズマシートから電離圏へのサブストーム擾乱の投影

*田中 高史1 (1.九州大学名誉教授)

キーワード:サブストーム

It has been believed that auroras observed in the ionosphere have their corresponding counterpart in the plasma sheet (Haerendel, 2011). Localized auroral breakup should reveal the location of explosive dissipation in the plasma sheet. Similar correspondence is supposed even during the growth phase. While it is well known that the prebreakup arc breakups first during the substorm, the equatorial location and relating formation mechanism of equatormost arc are long-standing questions in the understanding of the growth phase (Sergeev et al., 2012). Another aurora during the growth phase is the poleward bright arc that is believed to be an ionospheric projection of the reconnection separatrix. Also the equatorward extension of the N-S auroral arc has been suggested to be associated with eathward fast bursty flows (Nishimura et al., 2010). The region of aurora indicates that the width of oval is 7o (64o to 71o), near midnight just prior to the breakup. Pich angle isotropy boundary at 65.5o is critical for the prebreakup arc, since the isotropy boundary coincides with the prebreakup arc. Seen from the structure of isotropy boundary, the breakup arc is somewhere in the transition region between the dipole-like region and the current sheet region. A phenomenon closely related to the projection of the aurora is the distribution of FAC and its tracing. A traditional understanding for the driver of disturbances is the fast flow, both for the growth phase and the onset. The BBF was expected for a wide range of activity including localized auroral brightenings, N-S auroras and streamers (Nakamura et al., 2001). At the same time, the BBF can be a source of the FAC. The cross-tail current is diverted via downward FAC into the ionosphere on the eastward side of the bubble and is connected to upward FACs west of the bubble. The overall region 1-sense FACs is expected to emerge from 64o to 70o (Yang et al., 2012). The plasma ahead of the bubble is compressed, resulting in a high plasma pressure and the region 2-sense FACs that are as thin as 1o, centered at 63o. Recent M-I coupling simulation reproduces almost all signatures of the substorm, including the preonset arc, and the onset that start from the low-latitude side of the oval (Tanaka et al., 2010). From the numerical solution just prior tp the onset, the BBF region from x=-10 Re to x=-20 Re in the plasma sheet is projected down along the magnetic filed to a quite narrow region in the ionosphere from 65.7o to 66.8o latitudes. Even the outmost field line of the plasma sheet is traced down to 68o latitude in the ionosphere. So that the observed high-latitude part of the oval (68o~71o) is outside the plasma sheet. The N-S arc that usually starts from higher latitude than 70o cannot be the reflection of the BBF. Near the midnight, in the numerical solution, the region 1 FAC distributes from 65o to 69o (with strong part 67o~68o) and the region 2 FAC distributes from 62o to 64o latitude. From this result, the growth phase region 1 FAC cannot be from the plasma sheet. The result of current line tracing shows that the growth phase region 1 FAC extends into the magnetosphere as far as x=-20Re through the east-west flow shear between the tail plasma sheet and the lobe. If we look at only the latitude it is barely possible that the onset FAC strating from the lowest-latitude area of the region 1 FAC around 65o could be from the CW that should to be inside x=-10 Re (65.7o). However, it is implausible from the current line tracing. The onset region 1 FAC is mapped to the cusp-mantle region through the near earth flow shear between the plasma sheet and the lobe. Correspondence beween the plasma sheet and the ionosphere so far believed is quite confusing. It is doubtful to consider that all auroras observed in the ionosphere have their corresponding counterpart in the plasma sheet.