研究者業績
基本情報
- 所属
- 国立研究開発法人宇宙航空研究開発機構 宇宙科学研究所 教授
- 学位
- 理学博士(1998年3月 早稲田大学)
- J-GLOBAL ID
- 200901062235719944
- researchmap会員ID
- 1000320874
研究分野
4学歴
1-
- 1998年
論文
171-
AGU Advances 7(3) 2026年6月4日Abstract Pulsating aurorae are prominent auroral emissions in the polar regions, typically occurring in the morning hours during the recovery phase of auroral substorms. These aurorae usually consist of round‐shaped patches of emission, with luminosity that pulsates at intervals ranging from less than a second to several tens of seconds. Here, we present, for the first time, a unique case of a pulsating aurora that expanded radially outward in all the directions and repeatedly formed a ring‐shaped structure. The speed of expansion, which was at least several tens of kilometers per second at ionospheric altitudes, cannot be attributed to the horizontal convective motion of plasma in the ionosphere. In the magnetosphere, corresponding to the expanding ring‐shaped aurora, the Arase satellite detected successive enhancements of natural electromagnetic waves known as a “chorus.” These chorus waves scatter energetic magnetospheric electrons into the ionosphere, resulting in pulsating diffuse aurorae. Notably, the satellite observed systematic delay in the timing of chorus detections, which suggests that a similar circularly expanding feature existed in space. These simultaneous observations of expanding features in both the ionosphere and the magnetosphere demonstrate that the temporal evolution of the shape of a pulsating aurora manifests the spatiotemporal evolution of the source of plasma waves in space.
-
Journal of Geophysical Research: Space Physics 131(4) 2026年4月3日Abstract Analyzing the dynamics of trapped electron fluxes in the Earth's outer radiation belt is a complex task, due to the presence of insufficiently known parameters and the long runtimes of multi‐dimensional radiation belt codes, preventing a thorough examination of dependencies on all parameters. Here, we present an approximate eigenfunction modeling of whistler‐mode wave‐driven electron pitch‐angle diffusion, slightly generalized compared to previous work. This new model can approximately describe, in an easy, flexible, and fast way, both the asymptotic electron pitch‐angle distribution (PAD) at all pitch angles and its temporal evolution toward this final state, in both weak and strong diffusion regimes, in the presence of a finite, time‐varying electron source. In this model, wave‐driven pitch‐angle diffusion is assumed to prevail over energy diffusion and radial diffusion, limiting its applicability to the plasmasphere or intervals of smooth decay of the electron flux outside the plasmasphere, during moderately active periods. We propose a new method, based on this model, for estimating the energy spectrum and temporal variation of the electron source. We investigate the dynamics of the electron flux measured by the Van Allen Probes and Arase spacecraft during two events in 2018 and 2022 in the outer radiation belt. We demonstrate that the new model can reproduce the evolution of the measured electron flux and of its PAD, provided that the magnitude of diffusion rates is normalized to the observed decay timescale in the 300–600 keV range and that a finite electron source term is included below 300 keV.
-
Applied Thermal Engineering 291 130129-130129 2026年4月
-
Journal of Geophysical Research: Space Physics 131(4) 2026年3月28日Abstract The May 2024 geomagnetic superstorm provided the opportunity to explore how strong wave‐particle interactions affect energetic electron precipitation under intense driving. Using coordinated measurements from a balloon‐borne Timepix‐based X‐ray detector, ground‐based riometers and magnetometers, and Arase satellite observations, we identified quasi‐periodic bursts of energetic electron precipitation coincident with Pc5 ultra low frequency (ULF) wave oscillations. Arase satellite data revealed energy‐dispersed trapped energetic electron flux modulations in the “seed” energy range, indicating that trapped electron flux was likely modulated by ULF waves. This letter reveals that these flux enhancements surpassed the Kennel‐Petschek (K‐P) limit, creating intense chorus waves and driving periodic electron precipitation. Drift‐dispersion analysis traced these modulations back to a source in the post‐noon magnetospheric sector, matching balloon and ground‐based measurements. Here, we propose a novel indirect ULF wave‐driven mechanism for modulated energetic electron precipitation, whereby periodic modulations of “seed” electron fluxes enhance electron losses.
-
GEOPHYSICAL RESEARCH LETTERS 53(3) 2026年2月1日
MISC
204-
日本物理学会講演概要集 61(1) 18-18 2006年3月4日
-
日本物理学会講演概要集 60(2) 48-48 2005年8月19日
-
日本物理学会講演概要集 60(2) 41-41 2005年8月19日
-
日本物理学会講演概要集 60(2) 14-14 2005年8月19日
-
日本物理学会講演概要集 60(1) 217-217 2005年3月4日
-
2005年2月16日On December 27, 2004, plasma particle detectors on the GEOTAIL spacecraft detected an extremely strong signal of hard X-ray photons from the giant flare of SGR1806-20, a magnetar candidate. While practically all gamma-ray detectors on any satellites were saturated during the first ~500 ms interval after the onset, one of the particle detectors on GEOTAIL was not saturated and provided unique measurements of the hard X-ray intensity and the profile for the first 600 ms interval with 5.48 ms time resolution. After ~50 ms from the initial rapid onset, the peak photon flux (integrated above ~50 keV) reached the order of 10^7 photons sec^{-1} cm^{-2}. Assuming a blackbody spectrum with kT=175 keV, we estimate the peak energy flux to be 21 erg sec^{-1} cm^{-2} and the fluence (for 0-600 ms) to be 2.4 erg cm^{-2}. The implied energy release comparable to the magnetic energy stored in a magnetar (~10^{47} erg) suggests an extremely efficient energy release mechanism.
-
IEEE TRANSACTIONS ON NUCLEAR SCIENCE 51(5) 2004-2007 2004年10月
-
IEEE Nuclear Science Symposium Conference Record 2 813-816 2003年12月1日
-
IEEE Nuclear Science Symposium Conference Record 5 3588-3592 2003年12月1日
-
宇宙生物科学 = Biological sciences in space 15 s131 2001年10月
-
日本惑星科学会秋期講演会予稿集 2000 59-59 2000年10月31日月周回衛星セレーネに搭載されるγ線分光計GRSの現状を報告する。GRSは約250cc n型高純度ゲルマニウム結晶を月探査用として初めて採用し、BGOとプラスチックシンチレータを反同時計数計として用いることでゲルマニウム検出器の持つ高分解能を維持する。ゲルマニウム結晶は計測時に冷却する必要があるが、スターリング冷凍機を用いて80-90K程度に冷却を行う。その結果セレーネGRSはLunar Prospectorに搭載されたガンマ線分光計の2倍、APOLLO GRSの4倍以上の高感度を持つ。したがって、非常に高い精度で月表面から放出されるガンマ線を測り、O、Mg、Al、Si、Ti、Feといった主要元素や、K、Th、Uなどの放射性元素を同定、定量化する。また、もし極域に氷が存在すれば、GRSは非常にエネルギー分解能が高いので、水素からの即発ガンマ線を検出でき、水の場所の特定、存在量を求めることができる。
-
TRANSPORT OF GALACTIC AND ANOMALOUS COSMIC RAYS IN THE HELIOSPHERE: OBSERVATIONS, SIMULATIONS AND THEORY 23(3) 487-490 1999年
-
宇宙生物科学 = Biological sciences in space 11(4) 355-364 1997年12月1日
-
ASTROPHYSICAL JOURNAL 477(2) L111-L113 1997年3月
-
NIRS-M (National Inst. of Radiological Sciences) (120) 1997年
共同研究・競争的資金等の研究課題
30-
日本学術振興会 科学研究費助成事業 2020年4月 - 2023年3月
-
日本学術振興会 科学研究費助成事業 基盤研究(A) 2016年4月 - 2020年3月
-
日本学術振興会 科学研究費助成事業 若手研究(A) 2014年4月 - 2017年3月
-
日本学術振興会 科学研究費助成事業 2012年6月 - 2017年3月
-
日本学術振興会 科学研究費助成事業 基盤研究(A) 2012年4月 - 2016年3月