宇宙科学広報・普及主幹付

Takeshi Takashima

  (高島 健)

Profile Information

Affiliation
Professer, Institute of Space and Astronautical Science, Japan Aerospace Exploration Agency
Degree
Ph. D(Mar, 1998, Waseda University)

J-GLOBAL ID
200901062235719944
researchmap Member ID
1000320874

Education

 1

Papers

 158
  • Zijin Zhang, Anton Artemyev, Didier Mourenas, Vassilis Angelopoulos, Xiao‐Jia Zhang, S. Kasahara, Y. Miyoshi, A. Matsuoka, Y. Kasahara, T. Mitani, S. Yokota, T. Hori, K. Keika, T. Takashima, M. Teramoto, S. Matsuda, I. Shinohara
    Journal of Geophysical Research: Space Physics, 129(12), Dec 13, 2024  
    Abstract We investigate the dynamics of relativistic electrons in the Earth's outer radiation belt by analyzing the interplay of several key physical processes: electron losses due to pitch angle scattering from electromagnetic ion cyclotron (EMIC) waves and chorus waves, and electron flux increases from chorus wave‐driven acceleration of 100–300 keV seed electrons injected from the plasma sheet. We examine a weak geomagnetic storm on 17 April 2021, using observations from various spacecraft, including GOES, Van Allen Probes, ERG/ARASE, MMS, ELFIN, and POES. Despite strong EMIC‐ and chorus wave‐driven electron precipitation in the outer radiation belt, trapped 0.1–1.5 MeV electron fluxes actually increased. We use theoretical estimates of electron quasi‐linear diffusion rates by chorus and EMIC waves, based on statistics of their wave power distribution, to examine the role of those waves in the observed relativistic electron flux variations. We find that a significant supply of 100–300 keV electrons by plasma sheet injections together with chorus wave‐driven acceleration can overcome the rate of chorus and EMIC wave‐driven electron losses through pitch angle scattering toward the loss cone, explaining the observed net increase in electron fluxes. Our study emphasizes the importance of simultaneously taking into account resonant wave‐particle interactions and modeled local energy gradients of electron phase space density following injections, to accurately forecast the dynamical evolution of trapped electron fluxes.
  • Weiqin Sun, Xiao‐Jia Zhang, Anton V. Artemyev, Didier Mourenas, Steven K. Morley, Vassilis Angelopoulos, S. Kasahara, Y. Miyoshi, A. Matsuoka, T. Mitani, S. Yokota, T. Hori, K. Keika, T. Takashima, M. Teramoto, I. Shinohara, K. Yamamoto
    Journal of Geophysical Research: Space Physics, 129(11), Oct 28, 2024  
    Abstract Near‐equatorial measurements of energetic electron fluxes, in combination with numerical simulation, are widely used for monitoring of the radiation belt dynamics. However, the long orbital periods of near‐equatorial spacecraft constrain the cadence of observations to once per several hours or greater, that is, much longer than the mesoscale injections and rapid local acceleration and losses of energetic electrons of interest. An alternative approach for radiation belt monitoring is to use measurements of low‐altitude spacecraft, which cover, once per hour or faster, the latitudinal range of the entire radiation belt within a few minutes. Such an approach requires, however, a procedure for mapping the flux from low equatorial pitch angles (near the loss cone) as measured at low altitude, to high equatorial pitch angles (far from the loss cone), as necessitated by equatorial flux models. Here we do this using the high energy resolution ELFIN measurements of energetic electrons. Combining those with GPS measurements we develop a model for the electron anisotropy coefficient, , that describes electron flux dependence on equatorial pitch‐angle, , . We then validate this model by comparing its equatorial predictions from ELFIN with in‐situ near‐equatorial measurements from Arase (ERG) in the outer radiation belt.
  • Vladimir Borisovich Belakhovsky, Vyacheslav A. Pilipenko, Elizaveta E. Antonova, Yoshizumi Miyoshi, Yoshiya Kasahara, Satoshi Kasahara, Nana Higashio, Iku Shinohara, Tomoaki Hori, Shoya Matsuda, Shoichiro Yokota, Takeshi Takashima, Mitani Takefumi, Kunihiro Keika, Satoko Nakamura
    Earth, Planets and Space, 75(1), Dec 21, 2023  
    Abstract Variations of relativistic electron fluxes (E ≥ 1 MeV) and wave activity in the Earth magnetosphere are studied to determine the contribution of different acceleration mechanisms of the outer radiation belt electrons: ULF mechanism, VLF mechanism, and adiabatic acceleration. The electron fluxes were measured by Arase satellite and geostationary GOES satellites. The ULF power index is used to characterize the magnetospheric wave activity in the Pc5 range. To characterize the VLF wave activity in the magnetosphere, we use data from PWE instrument of Arase satellite. We consider some of the most powerful magnetic storms during the Arase era: May 27–29, 2017; September 7–10, 2017; and August 25–28, 2018. Also, non-storm intervals with a high solar wind speed before and after these storms for comparison are analyzed. Magnitudes of relativistic electron fluxes during these magnetic storms are found to be greater than that during non-storm intervals with high solar wind streams. During magnetic storms, the flux intensity maximum shifts to lower L-shells compared to intervals without magnetic storms. For the considered events, the substorm activity, as characterized by AE index, is found to be a necessary condition for the increase of relativistic electron fluxes, whereas a high solar wind speed alone is not sufficient for the relativistic electron growth. The enhancement of relativistic electron fluxes by 1.5–2 orders of magnitude is observed 1–3 days after the growth of the ULF index and VLF emission power. The growth of VLF and ULF wave powers coincides with the growth of substorm activity and occurs approximately at the same time. Both mechanisms operate at the first phase of electron acceleration. At the second phase of electron acceleration, the mechanism associated with the injection of electrons into the region of the magnetic field weakened by the ring current and their subsequent betatron acceleration during the magnetic field restoration can work effectively. Graphical Abstract
  • Hiroyuki TOYOTA, Takeshi TAKASHIMA, Hiroshi IMAMURA, Kazutaka NISHIYAMA, Takayuki YAMAMOTO, Takeshi MIYABARA, Masayuki OHTA, Yoshitaka MOCHIHARA, Naoya OZAKI, Hiroyuki NAGAMATSU, Takakazu OKAHASHI, Junko TAKAHASHI, Toshiaki OKUDAIRA, Takayuki HIRAI, Masanori KOBAYASHI, Ko ISHIBASHI, Peng HONG, Osamu OKUDAIRA, Tomoko ARAI
    Journal of Evolving Space Activities, 1, Dec, 2023  Peer-reviewed
  • Yoshizumi Miyoshi, Yuto Katoh, Shinji Saito, Takefumi Mitani, Takeshi Takashima
    Solar-Terrestrial Environmental Prediction, 115-137, Feb 1, 2023  

Misc.

 175
  • 成影典之, 岡光夫, 松崎恵一, 渡辺伸, 坂尾太郎, 萩野浩一, 三石郁之, 深沢泰司, 水野恒史, 篠原育, 川手朋子, 下条圭美, 高棹真介, 金子岳史, 田辺博士, 上野宗孝, 高橋忠幸, 高島健, 太田方之
    日本天文学会年会講演予稿集, 2023, 2023  
  • 徳留真一郎, 餅原義孝, 三浦政司, 坂本勇樹, 森下直樹, 山本高行, 荒川聡, 竹内伸介, 竹前俊昭, 豊田裕之, 奥平俊暁, 太刀川純孝, 寺島啓太, 紙田徹, 今村裕志, 高島健
    宇宙科学技術連合講演会講演集(CD-ROM), 67th, 2023  
  • 秋月祐樹, 澤田健一郎, 金城富宏, 小川博之, 西山和孝, 豊田博之, 今村裕志, 高島健
    宇宙科学技術連合講演会講演集(CD-ROM), 67th, 2023  
  • 須崎祐多, HONG Peng K., 石橋高, 宮原剛, 太田方之, 細沼貴之, 尾崎直哉, 豊田裕之, 西山和孝, 大槻真嗣, 奥平修, 佐藤峻介, 高島健, 豊永洸大, 藤島早織, 萩原啓司
    宇宙科学技術連合講演会講演集(CD-ROM), 67th, 2023  
  • 荒井朋子, 小林正規, 石橋高, 木村宏, 平井隆之, 岡本尚也, 山田学, 吉田二美, 吉田二美, 秋田谷洋, 千秋博紀, 和田浩二, SRAMA Ralf, HARALD Krueger, MARSHALL Sean, MARSHALL Sean, 佐々木晶, 薮田ひかる, 石黒正晃, 関口朋彦, 浦川聖太郎, 渡部潤一, 伊藤孝士, 大坪貴文, 大塚勝仁, 阿部新助, 中村智樹, 廣井孝弘, 諸田智克, 紅山仁, 橘省吾, 三河内岳, 野口高明, 中村メッセンジャー圭子, 小松睦美, 金田英宏, 小松吾郎, 小松吾郎, 出村裕英, 平田成, 伊藤元雄, 山口亮, 松浦周二, 巽瑛理, 柳沢俊史, 黒崎裕久, 矢野創, 吉川真, 尾崎直哉, 山本高行, 豊田裕之, 西山和孝, 今村裕志, 高島健
    宇宙科学技術連合講演会講演集(CD-ROM), 67th, 2023  

Research Projects

 25