Dept. of Solar System Sciences

Takefumi MITANI

  (三谷 烈史)

Profile Information

Affiliation
Assistant Professor, Institute of Space and Astronautical Science, Japan Aerospace Exploration Agency
Degree
修士(理学)(東京大学)
博士(理学)(東京大学)

J-GLOBAL ID
201901006861784502
researchmap Member ID
B000359529

Committee Memberships

 1

Papers

 86
  • K. Hosokawa, Y. Miyoshi, M. Mcharg, V. Ledvina, D. Hampton, M. Lessard, M. Shumko, K. Asamura, T. Sakanoi, T. Mitani, T. Namekawa, M. Nosé, Y. Ogawa, A. Jaynes, A. Halford
    Journal of Geophysical Research: Space Physics, Nov, 2024  
  • 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.
  • Zijin Zhang, Anton V Artemyev, Didier Mourenas, Vassilis Angelopoulos, Xiao-Jia Zhang, Satoshi Kasahara, Yoshizumi Miyoshi, Ayako Matsuoka, Yoshiya Kasahara, Takefumi Mitani, Shoichiro Yokota, Tomoaki Hori, Kunihiro Keika, Takeshi Takashima, Mariko Teramoto, Shoya Matsuda, Iku Shinohara
    Aug 15, 2024  
  • Masahito Nosé, Keisuke Hosokawa, Reiko Nomura, Mariko Teramoto, Kazushi Asamura, Yoshizumi Miyoshi, Takefumi Mitani, Takeshi Sakanoi, Taku Namekawa, Takeshi Kawano, Yoshihiro Iwanaga, Shunichi Tatematsu, Masafumi Hirahara, Alexa Halford, Mykhaylo Shumko, Marc R. Lessard, Kristina Lynch, Nicholaos Paschalidis, Allison N. Jaynes, Matthew G. McHarg
    Journal of Geophysical Research: Space Physics, 129(6), May 31, 2024  
    Abstract We made observations of magnetic field variations in association with pulsating auroras with the magneto‐impedance sensor magnetometer (MIM) carried by the Loss through Auroral Microburst Pulsations (LAMP) sounding rocket that was launched at 11:27:30 UT on 5 March 2022 from Poker Flat Research Range, Alaska. At an altitude of 200–250 km, MIM detected clear enhancements of the magnetic field by 15–25 nT in both the northward and westward components. From simultaneous observations with the ground all‐sky camera, we found that the footprint of LAMP at the 100 km altitude was located near the center of a pulsating auroral patch. The auroral patch had a dimension of ∼90 km in latitude and ∼25 km in longitude, and its major axis was inclined toward northwest. These observations were compared with results of a simple model calculation, in which local electron precipitation into the thin‐layer ionosphere causes an elliptical auroral patch. The conductivity within the patch is enhanced in the background electric field and as a result, the magnetic field variations are induced around the auroral patch. The model calculation results can explain the MIM observations if the electric field points toward southeast and one of the model parameters is adjusted. We conclude that the pulsating auroral patch in this event was associated with a one‐pair field‐aligned current that consists of downward (upward) currents at the poleward (equatorward) edge of the patch. This current structure is maintained even if the auroral patch is latitudinally elongated.
  • T. Namekawa, T. Mitani, K. Asamura, Y. Miyoshi, K. Hosokawa, M. Lessard, C. Moser, A. J. Halford, T. Sakanoi, M. Kawamura, M. Nose, R. Nomura, M. Teramoto, M. Shumko, K. A. Lynch, A. N. Jaynes, M. G. McHarg
    Geophysical Research Letters, Dec 28, 2023  Peer-reviewed

Misc.

 139

Research Projects

 8