Your search keyword '"Kasaba, Y. (Yasumasa)"' showing total 2 results

1. Plasma and field observations in the magnetospheric source region of a stable auroral red (SAR) arc by the Arase satellite on 28 March 2017

Author

Inaba, Y. (Yudai), Shiokawa, K. (Kazuo), Oyama, S. (Shin‐ichiro), Otsuka, Y. (Yuichi), Oksanen, A. (Arto), Shinbori, A. (Atsuki), Gololobov, A. Y. (Artem Yu), Miyoshi, Y. (Yoshizumi), Kazama, Y. (Yoichi), Wang, S. (Shiang‐Yu), Tam, S. W. (Sunny W. Y.), Chang, T. (Tzu‐Fang), Wang, B. (Bo‐Jhou), Yokota, S. (Shoichiro), Kasahara, S. (Satoshi), Keika, K. (Kunihiro), Hori, T. (Tomoaki), Matsuoka, A. (Ayako), Kasahara, Y. (Yoshiya), Kumamoto, A. (Atsushi), Kasaba, Y. (Yasumasa), Tsuchiya, F. (Fuminori), Shoji, M. (Masafumi), Shinohara, I. (Iku), Stolle, C. (Claudia), Inaba, Y. (Yudai), Shiokawa, K. (Kazuo), Oyama, S. (Shin‐ichiro), Otsuka, Y. (Yuichi), Oksanen, A. (Arto), Shinbori, A. (Atsuki), Gololobov, A. Y. (Artem Yu), Miyoshi, Y. (Yoshizumi), Kazama, Y. (Yoichi), Wang, S. (Shiang‐Yu), Tam, S. W. (Sunny W. Y.), Chang, T. (Tzu‐Fang), Wang, B. (Bo‐Jhou), Yokota, S. (Shoichiro), Kasahara, S. (Satoshi), Keika, K. (Kunihiro), Hori, T. (Tomoaki), Matsuoka, A. (Ayako), Kasahara, Y. (Yoshiya), Kumamoto, A. (Atsushi), Kasaba, Y. (Yasumasa), Tsuchiya, F. (Fuminori), Shoji, M. (Masafumi), Shinohara, I. (Iku), and Stolle, C. (Claudia)

Abstract

A stable auroral red (SAR) arc is an aurora with a dominant 630 nm emission at subauroral latitudes. SAR arcs have been considered to occur due to the spatial overlap between the plasmasphere and the ring‐current ions. In the overlap region, plasmaspheric electrons are heated by ring‐current ions or plasma waves, and their energy is then transferred down to the ionosphere where it causes oxygen red emission. However, there have been no study conducted so far that quantitatively examined plasma and electromagnetic fields in the magnetosphere associated with SAR arc. In this paper, we report the first quantitative evaluation of conjugate measurements of a SAR arc observed at 2204 UT on 28 March 2017 and investigate its source region using an all‐sky imager at Nyrölä (magnetic latitude: 59.4°N), Finland, and the Arase satellite. The Arase observation shows that the SAR arc appeared in the overlap region between a plasmaspheric plume and the ring‐current ions and that electromagnetic ion cyclotron waves and kinetic Alfven waves were not observed above the SAR arc. The SAR arc was located at the ionospheric trough minimum identified from a total electron content map obtained by the GNSS receiver network. The Swarm satellite flying in the ionosphere also passed the SAR arc at ~2320 UT and observed a decrease in electron density and an increase in electron temperature during the SAR‐arc crossing. These observations suggest that the heating of plasmaspheric electrons via Coulomb collision with ring‐current ions is the most plausible mechanism for the SAR‐arc generation.

Published

2020

2. Visualization of rapid electron precipitation via chorus element wave-particle interactions

Author

Ozaki, M. (Mitsunori), Miyoshi, Y. (Yoshizumi), Shiokawa, K. (Kazuo), Hosokawa, K. (Keisuke), Oyama, S.-i. (Shin-ichiro), Kataoka, R. (Ryuho), Ebihara, Y. (Yusuke), Ogawa, Y. (Yasunobu), Kasahara, Y. (Yoshiya), Yagitani, S. (Satoshi), Kasaba, Y. (Yasumasa), Kumamoto, A. (Atsushi), Tsuchiya, F. (Fuminori), Matsuda, S. (Shoya), Katoh, Y. (Yuto), Hikishima, M. (Mitsuru), Kurita, S. (Satoshi), Otsuka, Y. (Yuichi), Moore, R. C. (Robert C.), Tanaka, Y. (Yoshimasa), Nose, M. (Masahito), Nagatsuma, T. (Tsutomu), Nishitani, N. (Nozomu), Kadokura, A. (Akira), Connors, M. (Martin), Inoue, T. (Takumi), Matsuoka, A. (Ayako), Shinohara, I. (Iku), Ozaki, M. (Mitsunori), Miyoshi, Y. (Yoshizumi), Shiokawa, K. (Kazuo), Hosokawa, K. (Keisuke), Oyama, S.-i. (Shin-ichiro), Kataoka, R. (Ryuho), Ebihara, Y. (Yusuke), Ogawa, Y. (Yasunobu), Kasahara, Y. (Yoshiya), Yagitani, S. (Satoshi), Kasaba, Y. (Yasumasa), Kumamoto, A. (Atsushi), Tsuchiya, F. (Fuminori), Matsuda, S. (Shoya), Katoh, Y. (Yuto), Hikishima, M. (Mitsuru), Kurita, S. (Satoshi), Otsuka, Y. (Yuichi), Moore, R. C. (Robert C.), Tanaka, Y. (Yoshimasa), Nose, M. (Masahito), Nagatsuma, T. (Tsutomu), Nishitani, N. (Nozomu), Kadokura, A. (Akira), Connors, M. (Martin), Inoue, T. (Takumi), Matsuoka, A. (Ayako), and Shinohara, I. (Iku)

Abstract

Chorus waves, among the most intense electromagnetic emissions in the Earth’s magnetosphere, magnetized planets, and laboratory plasmas, play an important role in the acceleration and loss of energetic electrons in the plasma universe through resonant interactions with electrons. However, the spatial evolution of the electron resonant interactions with electromagnetic waves remains poorly understood owing to imaging difficulties. Here we provide a compelling visualization of chorus element wave–particle interactions in the Earth’s magnetosphere. Through in-situ measurements of chorus waveforms with the Arase satellite and transient auroral flashes from electron precipitation events as detected by 100-Hz video sampling from the ground, Earth’s aurora becomes a display for the resonant interactions. Our observations capture an asymmetric spatial development, correlated strongly with the amplitude variation of discrete chorus elements. This finding is not theoretically predicted but helps in understanding the rapid scattering processes of energetic electrons near the Earth and other magnetized planets.

Published

2019