Earth, Planets and Space (Aug 2020)

Oxygen torus and its coincidence with EMIC wave in the deep inner magnetosphere: Van Allen Probe B and Arase observations

  • M. Nosé,
  • A. Matsuoka,
  • A. Kumamoto,
  • Y. Kasahara,
  • M. Teramoto,
  • S. Kurita,
  • J. Goldstein,
  • L. M. Kistler,
  • S. Singh,
  • A. Gololobov,
  • K. Shiokawa,
  • S. Imajo,
  • S. Oimatsu,
  • K. Yamamoto,
  • Y. Obana,
  • M. Shoji,
  • F. Tsuchiya,
  • I. Shinohara,
  • Y. Miyoshi,
  • W. S. Kurth,
  • C. A. Kletzing,
  • C. W. Smith,
  • R. J. MacDowall,
  • H. Spence,
  • G. D. Reeves

DOI
https://doi.org/10.1186/s40623-020-01235-w
Journal volume & issue
Vol. 72, no. 1
pp. 1 – 17

Abstract

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Abstract We investigate the longitudinal structure of the oxygen torus in the inner magnetosphere for a specific event found on 12 September 2017, using simultaneous observations from the Van Allen Probe B and Arase satellites. It is found that Probe B observed a clear enhancement in the average plasma mass (M) up to 3–4 amu at L = 3.3–3.6 and magnetic local time (MLT) = 9.0 h. In the afternoon sector at MLT ~ 16.0 h, both Probe B and Arase found no clear enhancements in M. This result suggests that the oxygen torus does not extend over all MLT but is skewed toward the dawn. Since a similar result has been reported for another event of the oxygen torus in a previous study, a crescent-shaped torus or a pinched torus centered around dawn may be a general feature of the O+ density enhancement in the inner magnetosphere. We newly find that an electromagnetic ion cyclotron (EMIC) wave in the H+ band appeared coincidently with the oxygen torus. From the lower cutoff frequency of the EMIC wave, the ion composition of the oxygen torus is estimated to be 80.6% H+, 3.4% He+, and 16.0% O+. According to the linearized dispersion relation for EMIC waves, both He+ and O+ ions inhibit EMIC wave growth and the stabilizing effect is stronger for He+ than O+. Therefore, when the H+ fraction or M is constant, the denser O+ ions are naturally accompanied by the more tenuous He+ ions, resulting in a weaker stabilizing effect (i.e., larger growth rate). From the Probe B observations, we find that the growth rate becomes larger in the oxygen torus than in the adjacent regions in the plasma trough and the plasmasphere.

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