EMIC Waves Converted From Equatorial Noise Due to M/Q = 2 Ions in the Plasmasphere: Observations From Van Allen Probes and Arase

Y. Miyoshi; S. Matsuda; S. Kurita; K. Nomura; K. Keika; M. Shoji; N. Kitamura; Y. Kasahara; A. Matsuoka; I. Shinohara; K. Shiokawa; S. Machida; O. Santolik; S. A. Boardsen; R. B. Horne; J. F. Wygant

doi:10.1029/2019GL083024

EMIC Waves Converted From Equatorial Noise Due to M/Q = 2 Ions in the Plasmasphere: Observations From Van Allen Probes and Arase

Y. Miyoshi, S. Matsuda, S. Kurita, K. Nomura, K. Keika, M. Shoji, N. Kitamura, Y. Kasahara, A. Matsuoka, I. Shinohara, K. Shiokawa, S. Machida, O. Santolik, S. A. Boardsen, R. B. Horne, J. F. Wygant

Physics and Astronomy (Twin Cities)

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29 Scopus citations

Abstract

Equatorial noise (EN) emissions are observed inside and outside the plasmapause. EN emissions are referred to as magnetosonic mode waves. Using data from Van Allen Probes and Arase, we found conversion from EN emissions to electromagnetic ion cyclotron (EMIC) waves in the plasmasphere and in the topside ionosphere. A low-frequency part of EN emissions becomes EMIC waves through branch splitting of EN emissions, and the mode conversion from EN to EMIC waves occurs around the frequency of M/Q = 2 (deuteron and/or alpha particles) cyclotron frequency. These processes result in plasmaspheric EMIC waves. We investigated the ion composition ratio by characteristic frequencies of EN emissions and EMIC waves and obtained ion composition ratios. We found that the maximum composition ratio of M/Q = 2 ions is ~10% below 3,000 km. The quantitative estimation of the ion composition will contribute to improving the plasma model of the deep plasmasphere and the topside ionosphere.

Original language	English (US)
Pages (from-to)	5662-5669
Number of pages	8
Journal	Geophysical Research Letters
Volume	46
Issue number	11
DOIs	https://doi.org/10.1029/2019GL083024
State	Published - Jun 16 2019

Bibliographical note

Publisher Copyright:
© 2019. The Authors.

Keywords

Arase
EMIC
M/Q = 2 ions
Van Allen Probes
magnetsonic waves
plasmasphere

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Miyoshi, Y., Matsuda, S., Kurita, S., Nomura, K., Keika, K., Shoji, M., Kitamura, N., Kasahara, Y., Matsuoka, A., Shinohara, I., Shiokawa, K., Machida, S., Santolik, O., Boardsen, S. A., Horne, R. B., & Wygant, J. F. (2019). EMIC Waves Converted From Equatorial Noise Due to M/Q = 2 Ions in the Plasmasphere: Observations From Van Allen Probes and Arase. Geophysical Research Letters, 46(11), 5662-5669. https://doi.org/10.1029/2019GL083024

Miyoshi, Y, Matsuda, S, Kurita, S, Nomura, K, Keika, K, Shoji, M, Kitamura, N, Kasahara, Y, Matsuoka, A, Shinohara, I, Shiokawa, K, Machida, S, Santolik, O, Boardsen, SA, Horne, RB & Wygant, JF 2019, 'EMIC Waves Converted From Equatorial Noise Due to M/Q = 2 Ions in the Plasmasphere: Observations From Van Allen Probes and Arase', Geophysical Research Letters, vol. 46, no. 11, pp. 5662-5669. https://doi.org/10.1029/2019GL083024

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abstract = "Equatorial noise (EN) emissions are observed inside and outside the plasmapause. EN emissions are referred to as magnetosonic mode waves. Using data from Van Allen Probes and Arase, we found conversion from EN emissions to electromagnetic ion cyclotron (EMIC) waves in the plasmasphere and in the topside ionosphere. A low-frequency part of EN emissions becomes EMIC waves through branch splitting of EN emissions, and the mode conversion from EN to EMIC waves occurs around the frequency of M/Q = 2 (deuteron and/or alpha particles) cyclotron frequency. These processes result in plasmaspheric EMIC waves. We investigated the ion composition ratio by characteristic frequencies of EN emissions and EMIC waves and obtained ion composition ratios. We found that the maximum composition ratio of M/Q = 2 ions is ~10% below 3,000 km. The quantitative estimation of the ion composition will contribute to improving the plasma model of the deep plasmasphere and the topside ionosphere.",

keywords = "Arase, EMIC, M/Q = 2 ions, Van Allen Probes, magnetsonic waves, plasmasphere",

author = "Y. Miyoshi and S. Matsuda and S. Kurita and K. Nomura and K. Keika and M. Shoji and N. Kitamura and Y. Kasahara and A. Matsuoka and I. Shinohara and K. Shiokawa and S. Machida and O. Santolik and Boardsen, {S. A.} and Horne, {R. B.} and Wygant, {J. F.}",

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T2 - Observations From Van Allen Probes and Arase

AU - Miyoshi, Y.

AU - Matsuda, S.

AU - Kurita, S.

AU - Nomura, K.

AU - Keika, K.

AU - Shoji, M.

AU - Kitamura, N.

AU - Kasahara, Y.

AU - Matsuoka, A.

AU - Shinohara, I.

AU - Shiokawa, K.

AU - Machida, S.

AU - Santolik, O.

AU - Boardsen, S. A.

AU - Horne, R. B.

AU - Wygant, J. F.

PY - 2019/6/16

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N2 - Equatorial noise (EN) emissions are observed inside and outside the plasmapause. EN emissions are referred to as magnetosonic mode waves. Using data from Van Allen Probes and Arase, we found conversion from EN emissions to electromagnetic ion cyclotron (EMIC) waves in the plasmasphere and in the topside ionosphere. A low-frequency part of EN emissions becomes EMIC waves through branch splitting of EN emissions, and the mode conversion from EN to EMIC waves occurs around the frequency of M/Q = 2 (deuteron and/or alpha particles) cyclotron frequency. These processes result in plasmaspheric EMIC waves. We investigated the ion composition ratio by characteristic frequencies of EN emissions and EMIC waves and obtained ion composition ratios. We found that the maximum composition ratio of M/Q = 2 ions is ~10% below 3,000 km. The quantitative estimation of the ion composition will contribute to improving the plasma model of the deep plasmasphere and the topside ionosphere.

AB - Equatorial noise (EN) emissions are observed inside and outside the plasmapause. EN emissions are referred to as magnetosonic mode waves. Using data from Van Allen Probes and Arase, we found conversion from EN emissions to electromagnetic ion cyclotron (EMIC) waves in the plasmasphere and in the topside ionosphere. A low-frequency part of EN emissions becomes EMIC waves through branch splitting of EN emissions, and the mode conversion from EN to EMIC waves occurs around the frequency of M/Q = 2 (deuteron and/or alpha particles) cyclotron frequency. These processes result in plasmaspheric EMIC waves. We investigated the ion composition ratio by characteristic frequencies of EN emissions and EMIC waves and obtained ion composition ratios. We found that the maximum composition ratio of M/Q = 2 ions is ~10% below 3,000 km. The quantitative estimation of the ion composition will contribute to improving the plasma model of the deep plasmasphere and the topside ionosphere.

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KW - EMIC

KW - M/Q = 2 ions

KW - Van Allen Probes

KW - magnetsonic waves

KW - plasmasphere

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EMIC Waves Converted From Equatorial Noise Due to M/Q = 2 Ions in the Plasmasphere: Observations From Van Allen Probes and Arase

Abstract

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Keywords

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