Your search keyword '"Kasahara, Yoshiya"' showing total 39 results

1. Comprehensive characterization of solar wind interaction with lunar crustal magnetic fields: Kaguya low-altitude observations.

Author

Ogino, Kohei, Harada, Yuki, Nishino, Masaki N., Saito, Yoshifumi, Yokota, Shoichiro, Kasahara, Yoshiya, Kumamoto, Atsushi, Takahashi, Futoshi, and Shimizu, Hisayoshi

Abstract

Although the Moon does not have a global intrinsic magnetic field, lunar crustal magnetic anomalies (LMAs) are nonuniformly distributed over the lunar surface. The interaction between the solar wind and LMAs leads to the formation of mini-magnetospheres. Since the spatial scales of LMAs are very small, below several tens of kilometers, solar wind ions are demagnetized while electrons are still magnetized, forming Hall electric fields typically at low altitudes ( < ∼ 30 km). Since direct observations of these interaction regions are challenging from typical nominal altitudes of lunar orbiters ( > ∼ 100 km), the solar wind-LMA interaction has not been fully understood. In this study, we analyze low-altitude data obtained by Kaguya over various LMAs to comprehensively characterize the plasma environment and electromagnetic fields in the solar wind-LMA interaction region. We observe strong solar wind ion reflection and whistler mode waves at 1–10 Hz under high solar wind dynamic pressure and strong interplanetary magnetic field conditions, respectively. These trends are particularly clear over spatially extended LMAs. Over both spatially isolated and extended LMAs, strong Broadband Electrostatic Noise at 1–10 kHz tends to be observed when the spacecraft is magnetically connected to the lunar surface. In addition, our results suggest that anti-moonward electrostatic fields at low altitudes contribute to the acceleration, deceleration, and reflection of incident solar wind particles, and the resulting modification of particle velocity distribution functions can strongly influence the nature of the solar wind-LMA interaction including plasma wave excitation. Based on Kaguya data, we also develop a predictable indicator of the central interaction region where solar wind ions and electrons are decoupled. We propose that this indicator can be utilized to define regions of interest for future low-altitude or lander missions to LMA. [ABSTRACT FROM AUTHOR]

Published

2024

2. On the phase difference of ECH waves obtained from the interferometry observation by the Arase satellite.

Author

Taki, Tomoe, Kurita, Satoshi, Shinjo, Airi, Fukasawa, Ibuki, Nakamura, Satoko, Kojima, Hirotsugu, Kasahara, Yoshiya, Matsuda, Shoya, Matsuoka, Ayako, Miyoshi, Yoshizumi, and Shinohara, Iku

Subjects

PHASE velocity, PLANE wavefronts, NUMERICAL calculations, INTERFEROMETRY, MAGNETIC fields

Abstract

We analyzed electrostatic electron cyclotron harmonic waves observed by the interferometry observation mode of the Arase satellite. It is found that the magnitude of the phase difference varies with the satellite spin. The spin dependence of this phase difference was investigated by examining the trend of the spin dependence for the 84 events of interferometry observation of ECH waves. We found that they are divided into two categories. One is that the phase difference tends to show sinusoidal variations as a function of the angle γ B between the ambient magnetic field projected on the spin plane and the electric field sensor. The other is that the phase difference is close to zero and does not depend on γ B . A numerical model of interferometry observation of single plane wave is constructed to explain the observed phase differences. We performed the numerical calculations when the background magnetic field was oriented in the direction often observed in the Arase satellite. The result of the calculations shows the wave vector direction relates to the spin angle with the maximum phase difference. Using this relation, we show that it may be possible to estimate the wave vector direction of ECH waves from one-dimensional interferometry data. This is expected to enable more accurate estimates of phase velocity. [ABSTRACT FROM AUTHOR]

Published

2024

3. Generation of equatorial plasma bubble after the 2022 Tonga volcanic eruption

Author

80270437, Shinbori, Atsuki, Sori, Takuya, Otsuka, Yuichi, Nishioka, Michi, Perwitasari, Septi, Tsuda, Takuo, Kumamoto, Atsushi, Tsuchiya, Fuminori, Matsuda, Shoya, Kasahara, Yoshiya, Matsuoka, Ayako, Nakamura, Satoko, Miyoshi, Yoshizumi, Shinohara, Iku, 80270437, Shinbori, Atsuki, Sori, Takuya, Otsuka, Yuichi, Nishioka, Michi, Perwitasari, Septi, Tsuda, Takuo, Kumamoto, Atsushi, Tsuchiya, Fuminori, Matsuda, Shoya, Kasahara, Yoshiya, Matsuoka, Ayako, Nakamura, Satoko, Miyoshi, Yoshizumi, and Shinohara, Iku

Abstract

Equatorial plasma bubbles are a phenomenon of plasma density depletion with small-scale density irregularities, normally observed in the equatorial ionosphere. This phenomenon, which impacts satellite-based communications, was observed in the Asia-Pacific region after the largest-on-record January 15, 2022 eruption of the Tonga volcano. We used satellite and ground-based ionospheric observations to demonstrate that an air pressure wave triggered by the Tonga volcanic eruption could cause the emergence of an equatorial plasma bubble. The most prominent observation result shows a sudden increase of electron density and height of the ionosphere several ten minutes to hours before the initial arrival of the air pressure wave in the lower atmosphere. The propagation speed of ionospheric electron density variations was ~ 480–540 m/s, whose speed was higher than that of a Lamb wave (~315 m/s) in the troposphere. The electron density variations started larger in the Northern Hemisphere than in the Southern Hemisphere. The fast response of the ionosphere could be caused by an instantaneous transmission of the electric field to the magnetic conjugate ionosphere along the magnetic field lines. After the ionospheric perturbations, electron density depletion appeared in the equatorial and low-latitude ionosphere and extended at least up to ±25° in geomagnetic latitude.

Published

2023

4. Relativistic electron flux growth during storm and non-storm periods as observed by ARASE and GOES satellites.

Author

Belakhovsky, Vladimir Borisovich, Pilipenko, Vyacheslav A., Antonova, Elizaveta E., Miyoshi, Yoshizumi, Kasahara, Yoshiya, Kasahara, Satoshi, Higashio, Nana, Shinohara, Iku, Hori, Tomoaki, Matsuda, Shoya, Yokota, Shoichiro, Takashima, Takeshi, Takefumi, Mitani, Keika, Kunihiro, and Nakamura, Satoko

Subjects

RELATIVISTIC electrons, SOLAR wind, MAGNETIC storms, STORMS, GEOSTATIONARY satellites, RADIATION belts

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. [ABSTRACT FROM AUTHOR]

Published

2023

5. New aspects of the upper atmospheric disturbances caused by the explosive eruption of the 2022 Hunga Tonga–Hunga Ha'apai volcano.

Author

Shinbori, Atsuki, Otsuka, Yuichi, Sori, Takuya, Nishioka, Michi, Septi, Perwitasari, Tsuda, Takuo, Nishitani, Nozomu, Kumamoto, Atsushi, Tsuchiya, Fuminori, Matsuda, Shoya, Kasahara, Yoshiya, Matsuoka, Ayako, Nakamura, Satoko, Miyoshi, Yoshizumi, and Shinohara, Iku

Subjects

VOLCANIC eruptions, EXPLOSIVE volcanic eruptions, IONOSPHERIC disturbances, VOLCANOES, GRAVITY waves, ATMOSPHERIC waves, ACOUSTIC resonance

Abstract

The Hunga Tonga–Hunga Ha'apai (HTHH) undersea volcanic eruption that occurred at 04:15 UT on 15 January 2022 is one of the most explosive events in the modern era, and a vertical plume reached approximately 55 km, corresponding to a height of the lower mesosphere. The intense explosion and subsequent plume generated acoustic and atmospheric gravity waves detected by ground-based instruments worldwide. Because a global-scale atmospheric and ionospheric response to the large volcanic eruption has not yet been observed, it provides a unique opportunity to promote interdisciplinary studies of coupling processes in lithosphere–atmosphere–ionosphere with ground-based and satellite observations and modeling. Further, this event allows us to elucidate the propagation and occurrence features of traveling ionospheric disturbances, the generation of equatorial plasma bubbles, the cause of electron density holes around the volcano, and the magnetic conjugacy of magnetic field perturbations. The most notable point among these studies is that the medium-scale travelling traveling ionospheric disturbances (MSTIDs) have magnetic conjugacy even in the daytime ionosphere and are generated by an external electric field, such as an E-region dynamo field, due to the motions of neutrals in the thermosphere. This advocates a new generation mechanism of MSTIDs other than the neutral oscillation associated with atmospheric gravity waves and electrified MSTIDs, which are frequently observed during daytime and nighttime, respectively. This paper reviews the recent studies of atmospheric and ionospheric disturbances after the HTHH volcanic eruption and summarizes what we know from this extreme event analysis. Further, we analyzed new datasets not shown in previous studies to give some new insights to understanding of some related phenomena. As a result, we also found that 4-min plasma flow oscillations caused by the acoustic resonance appeared with the amplitude of approximately 30 m/s in the northern hemisphere a few hours before the initial arrival of the air pressure waves. The propagation direction was westward, which is the same as that of the daytime MSTIDs with a magnetic conjugate feature. This result suggests that the 4-min oscillations are generated by an external electric field transmitted to the northern hemisphere along magnetic field lines. [ABSTRACT FROM AUTHOR]

Published

2023

6. Whistler-mode waves in Mercury's magnetosphere observed by BepiColombo/Mio.

Author

Ozaki, Mitsunori, Yagitani, Satoshi, Kasaba, Yasumasa, Kasahara, Yoshiya, Matsuda, Shoya, Omura, Yoshiharu, Hikishima, Mitsuru, Sahraoui, Fouad, Mirioni, Laurent, Chanteur, Gérard, Kurita, Satoshi, Nakazawa, Satoru, and Murakami, Go

Published

2023

7. Generation of equatorial plasma bubble after the 2022 Tonga volcanic eruption.

Author

Shinbori, Atsuki, Sori, Takuya, Otsuka, Yuichi, Nishioka, Michi, Perwitasari, Septi, Tsuda, Takuo, Kumamoto, Atsushi, Tsuchiya, Fuminori, Matsuda, Shoya, Kasahara, Yoshiya, Matsuoka, Ayako, Nakamura, Satoko, Miyoshi, Yoshizumi, and Shinohara, Iku

Subjects

IONOSPHERIC electron density, VOLCANIC eruptions, PLASMA production, ATMOSPHERIC boundary layer, LAMB waves, ELECTRON density, PLASMA density, VOLCANIC activity prediction

Abstract

Equatorial plasma bubbles are a phenomenon of plasma density depletion with small-scale density irregularities, normally observed in the equatorial ionosphere. This phenomenon, which impacts satellite-based communications, was observed in the Asia-Pacific region after the largest-on-record January 15, 2022 eruption of the Tonga volcano. We used satellite and ground-based ionospheric observations to demonstrate that an air pressure wave triggered by the Tonga volcanic eruption could cause the emergence of an equatorial plasma bubble. The most prominent observation result shows a sudden increase of electron density and height of the ionosphere several ten minutes to hours before the initial arrival of the air pressure wave in the lower atmosphere. The propagation speed of ionospheric electron density variations was ~ 480–540 m/s, whose speed was higher than that of a Lamb wave (~315 m/s) in the troposphere. The electron density variations started larger in the Northern Hemisphere than in the Southern Hemisphere. The fast response of the ionosphere could be caused by an instantaneous transmission of the electric field to the magnetic conjugate ionosphere along the magnetic field lines. After the ionospheric perturbations, electron density depletion appeared in the equatorial and low-latitude ionosphere and extended at least up to ±25° in geomagnetic latitude. [ABSTRACT FROM AUTHOR]

Published

2023

8. Discovery of proton hill in the phase space during interactions between ions and electromagnetic ion cyclotron waves

Author

80270437, Shoji, Masafumi, Miyoshi, Yoshizumi, Kistler, Lynn M., Asamura, Kazushi, Matsuoka, Ayako, Kasaba, Yasumasa, Matsuda, Shoya, Kasahara, Yoshiya, Shinohara, Iku, 80270437, Shoji, Masafumi, Miyoshi, Yoshizumi, Kistler, Lynn M., Asamura, Kazushi, Matsuoka, Ayako, Kasaba, Yasumasa, Matsuda, Shoya, Kasahara, Yoshiya, and Shinohara, Iku

Abstract

A study using Arase data gives the first observational evidence that the frequency drift of electromagnetic ion cyclotron (EMIC) waves is caused by cyclotron trapping. EMIC emissions play an important role in planetary magnetospheres, causing scattering loss of radiation belt relativistic electrons and energetic protons. EMIC waves frequently show nonlinear signatures that include frequency drift and amplitude enhancements. While nonlinear growth theory has suggested that the frequency change is caused by nonlinear resonant currents owing to cyclotron trapping of the particles, observational evidence for this has been elusive. We survey the wave data observed by Arase from March, 2017 to September 2019, and find the best falling tone emission event, one detected on 11th November, 2017, for the wave particle interaction analysis. Here, we show for the first time direct evidence of the formation of a proton hill in phase space indicating cyclotron trapping. The associated resonance currents and the wave growth of a falling tone EMIC wave are observed coincident with the hill, as theoretically predicted.

Published

2021

9. Active auroral arc powered by accelerated electrons from very high altitudes

Author

70795848, 80270437, 90785495, Imajo, Shun, Miyoshi, Yoshizumi, Kazama, Yoichi, Asamura, Kazushi, Shinohara, Iku, Shiokawa, Kazuo, Kasahara, Yoshiya, Kasaba, Yasumasa, Matsuoka, Ayako, Wang, Shiang-Yu, Tam, Sunny W. Y., Chang, Tzu‑Fang, Wang, Bo‑Jhou, Angelopoulos, Vassilis, Jun, Chae-Woo, Shoji, Masafumi, Nakamura, Satoko, Kitahara, Masahiro, Teramoto, Mariko, Kurita, Satoshi, Hori, Tomoaki, 70795848, 80270437, 90785495, Imajo, Shun, Miyoshi, Yoshizumi, Kazama, Yoichi, Asamura, Kazushi, Shinohara, Iku, Shiokawa, Kazuo, Kasahara, Yoshiya, Kasaba, Yasumasa, Matsuoka, Ayako, Wang, Shiang-Yu, Tam, Sunny W. Y., Chang, Tzu‑Fang, Wang, Bo‑Jhou, Angelopoulos, Vassilis, Jun, Chae-Woo, Shoji, Masafumi, Nakamura, Satoko, Kitahara, Masahiro, Teramoto, Mariko, Kurita, Satoshi, and Hori, Tomoaki

Abstract

Bright, discrete, thin auroral arcs are a typical form of auroras in nightside polar regions. Their light is produced by magnetospheric electrons, accelerated downward to obtain energies of several kilo electron volts by a quasi-static electric field. These electrons collide with and excite thermosphere atoms to higher energy states at altitude of ~ 100 km; relaxation from these states produces the auroral light. The electric potential accelerating the aurora-producing electrons has been reported to lie immediately above the ionosphere, at a few altitudes of thousand kilometres1. However, the highest altitude at which the precipitating electron is accelerated by the parallel potential drop is still unclear. Here, we show that active auroral arcs are powered by electrons accelerated at altitudes reaching greater than 30, 000 km. We employ high-angular resolution electron observations achieved by the Arase satellite in the magnetosphere and optical observations of the aurora from a ground-based all-sky imager. Our observations of electron properties and dynamics resemble those of electron potential acceleration reported from low-altitude satellites except that the acceleration region is much higher than previously assumed. This shows that the dominant auroral acceleration region can extend far above a few thousand kilometres, well within the magnetospheric plasma proper, suggesting formation of the acceleration region by some unknown magnetospheric mechanisms.

Published

2021

10. Space-to-space very low frequency radio transmission in the magnetosphere using the DSX and Arase satellites.

Author

McCollough, James P., Miyoshi, Yoshizumi, Ginet, Gregory P., Johnston, William R., Su, Yi-Jiun, Starks, Michael J., Kasahara, Yoshiya, Kojima, Hirotsugu, Matsuda, Shoya, Shinohara, Iku, Song, Paul, Reinisch, Bodo W., Galkin, Ivan A., Inan, Umran S., Lauben, David S., Linscott, Ivan, Ling, Alan G., Allgeier, Shawn, Lambour, Richard, and Schoenberg, Jon

Subjects

RADIO transmitters & transmission, MAGNETOSPHERE, RADIO frequency, RADIATION belts, LOW temperature plasmas, ASTROPHYSICAL radiation

Abstract

Very low frequency (VLF) waves (about 3–30 kHz) in the Earth's magnetosphere interact strongly with energetic electrons and are a key element in controlling dynamics of the Van Allen radiation belts. Bistatic very low frequency (VLF) transmission experiments have recently been conducted in the magnetosphere using the high-power VLF transmitter on the Air Force Research Laboratory's Demonstration and Science Experiments (DSX) spacecraft and an electric field receiver onboard the Japan Aerospace Exploration Agency's Arase (ERG) spacecraft. On 4 September 2019, the spacecraft came within 410 km of each other and were in geomagnetic alignment. During this time, VLF signals were successfully transmitted from DSX to Arase, marking the first successful reception of a space-to-space VLF signal. Arase measurements were consistent with field-aligned propagation as expected from linear cold plasma theory. Details of the transmission event and comparison to VLF propagation model predictions are presented. The capability to directly inject VLF waves into near-Earth space provides a new way to study the dynamics of the radiation belts, ushering in a new era of space experimentation. [ABSTRACT FROM AUTHOR]

Published

2022

11. An event study on broadband electric field noises and electron distributions in the lunar wake boundary.

Author

Nishino, Masaki N., Kasahara, Yoshiya, Harada, Yuki, Saito, Yoshifumi, Tsunakawa, Hideo, Kumamoto, Atsushi, Yokota, Shoichiro, Takahashi, Futoshi, Matsushima, Masaki, Shibuya, Hidetoshi, Shimizu, Hisayoshi, Miyashita, Yukinaga, Goto, Yoshitaka, and Ono, Takayuki

Subjects

*ELECTRON distribution, *ELECTRIC noise, *INTERPLANETARY magnetic fields, *SOLAR wind, *ELECTRON beams, *ELECTRIC fields, *LUNAR surface

Abstract

Wave–particle interactions are fundamental processes in space plasma, and some plasma waves, including electrostatic solitary waves (ESWs), are recognised as broadband noises (BBNs) in the electric field spectral data. Spacecraft observations in recent decades have detected BBNs around the Moon, but the generation mechanism of the BBNs is not fully understood. Here, we study a wake boundary traversal with BBNs observed by Kaguya, which includes an ESW event previously reported by Hashimoto et al. Geophys Res Lett 37:L19204 https://doi.org/10.1029/2010GL044529 (2010). Focusing on the relation between BBNs and electron pitch-angle distribution functions, we show that upward electron beams from the nightside lunar surface are effective for the generation of BBNs, in contrast to the original interpretation by Hashimoto et al. Geophys Res Lett 37:L19204 https://doi.org/10.1029/2010GL044529 (2010) that high-energy electrons accelerated by strong ambipolar electric fields excite ESWs in the region far from the Moon. When the BBNs were observed by the Kaguya spacecraft in the wake boundary, the spacecraft's location was magnetically connected to the nightside lunar surface, and bi-streaming electron distributions of downward-going solar wind strahl component and upward-going field-aligned beams (at ∼ 124 eV) were detected. The interplanetary magnetic field was dominated by a positive B Z (i.e. the northward component), and strahl electrons travelled in the antiparallel direction to the interplanetary magnetic field (i.e. southward), which enabled the strahl electrons to precipitate onto the nightside lunar surface directly. The incident solar wind electrons cause negative charging of the nightside lunar surface, which generates downward electric fields that accelerate electrons from the nightside surface toward higher altitudes along the magnetic field. The bidirectional electron distribution is not a sufficient condition for the BBN generation, and the distribution of upward electron beams seems to be correlated with the BBNs. Ambipolar electric fields in the wake boundary should also contribute to the electron acceleration toward higher altitudes and further intrusion of the solar wind ions into the deeper wake. We suggest that solar wind ion intrusion into the wake boundary is also an important factor that controls the BBN generation by facilitating the influx of solar wind electrons there. [ABSTRACT FROM AUTHOR]

Published

2022

12. Discovery of proton hill in the phase space during interactions between ions and electromagnetic ion cyclotron waves.

Author

Shoji, Masafumi, Miyoshi, Yoshizumi, Kistler, Lynn M., Asamura, Kazushi, Matsuoka, Ayako, Kasaba, Yasumasa, Matsuda, Shoya, Kasahara, Yoshiya, and Shinohara, Iku

Subjects

PROTONS, CYCLOTRON waves, ELECTROMAGNETISM, MAGNETOSPHERE, PARTICLES

Abstract

A study using Arase data gives the first observational evidence that the frequency drift of electromagnetic ion cyclotron (EMIC) waves is caused by cyclotron trapping. EMIC emissions play an important role in planetary magnetospheres, causing scattering loss of radiation belt relativistic electrons and energetic protons. EMIC waves frequently show nonlinear signatures that include frequency drift and amplitude enhancements. While nonlinear growth theory has suggested that the frequency change is caused by nonlinear resonant currents owing to cyclotron trapping of the particles, observational evidence for this has been elusive. We survey the wave data observed by Arase from March, 2017 to September 2019, and find the best falling tone emission event, one detected on 11th November, 2017, for the wave particle interaction analysis. Here, we show for the first time direct evidence of the formation of a proton hill in phase space indicating cyclotron trapping. The associated resonance currents and the wave growth of a falling tone EMIC wave are observed coincident with the hill, as theoretically predicted. [ABSTRACT FROM AUTHOR]

Published

2021

13. ISEE_Wave: interactive plasma wave analysis tool.

Author

Matsuda, Shoya, Miyoshi, Yoshizumi, Nakamura, Satoko, Kitahara, Masahiro, Shoji, Masafumi, Hori, Tomoaki, Imajo, Shun, Chae-Woo, Jun, Kurita, Satoshi, Kasahara, Yoshiya, Matsuoka, Ayako, and Shinohara, Iku

Subjects

PLASMA sheaths, PLASMA waves, WAVE analysis, GRAPHICAL user interfaces, OCEAN wave power, SINGULAR value decomposition, RADIO frequency allocation, CORONAL mass ejections

Abstract

We have developed ISEE_Wave (Institute for Space-Earth Environmental Research, Nagoya University - Plasma Wave Analysis Tool), an interactive plasma wave analysis tool for electric and magnetic field waveforms observed by the plasma wave experiment aboard the Arase satellite. ISEE_Wave provides an integrated wave analysis environment on a graphical user interface, where users can visualize advanced wave properties, such as the electric and magnetic field wave power spectra, wave normal polar angle, polarization ellipse, planarity of polarization, and Poynting vector angle. Users can simply select a time interval for their analysis, and ISEE_Wave automatically downloads the waveform data, ambient magnetic field data, and spacecraft attitude data from the data archive repository of the ERG Science Center, and then performs necessary coordinate transformation and spectral matrix calculation. The singular value decomposition technique is used as the core technique for the wave property analysis of ISEE_Wave. On-demand analysis is possible by specifying the parameters of the wave property analysis as well as the plot styles using the graphical user interface of ISEE_Wave. The results can be saved as image files of plots and/or a tplot save file. ISEE_Wave aids in the identification of fine structures of observed plasma waves, wave mode identification, and wave propagation analysis. These properties can be used to understand plasma wave generation, propagation, and wave-particle interaction in the inner magnetosphere. ISEE_Wave can also be applied to general waveform data observed by other spacecraft by using the plug-in procedures to load the data. [ABSTRACT FROM AUTHOR]

Published

2021

14. Transient ionization of the mesosphere during auroral breakup: Arase satellite and ground-based conjugate observations at Syowa Station

Author

80342616, 90785495, Kataoka, Ryuho, Nishiyama, Takanori, Tanaka, Yoshimasa, Kadokura, Akira, Uchida, Herbert Akihito, Ebihara, Yusuke, Ejiri, Mitsumu K., Tomikawa, Yoshihiro, Tsutsumi, Masaki, Sato, Kaoru, Miyoshi, Yoshizumi, Shiokawa, Kazuo, Kurita, Satoshi, Kasahara, Yoshiya, Ozaki, Mitsunori, Hosokawa, Keisuke, Matsuda, Shoya, Shinohara, Iku, Takashima, Takeshi, Sato, Tatsuhiko, Mitani, Takefumi, Hori, Tomoaki, Higashio, Nana, 80342616, 90785495, Kataoka, Ryuho, Nishiyama, Takanori, Tanaka, Yoshimasa, Kadokura, Akira, Uchida, Herbert Akihito, Ebihara, Yusuke, Ejiri, Mitsumu K., Tomikawa, Yoshihiro, Tsutsumi, Masaki, Sato, Kaoru, Miyoshi, Yoshizumi, Shiokawa, Kazuo, Kurita, Satoshi, Kasahara, Yoshiya, Ozaki, Mitsunori, Hosokawa, Keisuke, Matsuda, Shoya, Shinohara, Iku, Takashima, Takeshi, Sato, Tatsuhiko, Mitani, Takefumi, Hori, Tomoaki, and Higashio, Nana

Abstract

Transient mesospheric echo in the VHF range was detected at an altitude of 65–70 km during the auroral breakup that occurred from 2220 to 2226 UT on June 30, 2017. During this event, the footprint of the Arase satellite was located within the field of view of the all-sky imagers at Syowa Station in the Antarctic. Auroral observations at Syowa Station revealed the dominant precipitation of relatively soft electrons during the auroral breakup. A corresponding spike in cosmic noise absorption was also observed at Syowa Station, while the Arase satellite observed a flux enhancement of > 100 keV electrons and a broadband noise without detecting chorus waves or electromagnetic ion cyclotron waves. A general-purpose Monte Carlo particle transport simulation code was used to quantitatively evaluate the ionization in the middle atmosphere. Results of this study indicate that the precipitation of energetic electrons of > 100 keV, rather than X-rays from the auroral electrons, played a dominant role in the transient and deep (65–70 km) mesospheric ionization during the observed auroral breakup.

Published

2019

15. Visualization of rapid electron precipitation via chorus element wave–particle interactions

Author

80342616, 90785495, 80270437, Ozaki, Mitsunori, Miyoshi, Yoshizumi, Shiokawa, Kazuo, Hosokawa, Keisuke, Oyama, Shin-ichiro, Kataoka, Ryuho, Ebihara, Yusuke, Ogawa, Yasunobu, Kasahara, Yoshiya, Yagitani, Satoshi, Kasaba, Yasumasa, Kumamoto, Atsushi, Tsuchiya, Fuminori, Matsuda, Shoya, Katoh, Yuto, Hikishima, Mitsuru, Kurita, Satoshi, Otsuka, Yuichi, Moore, Robert C., Tanaka, Yoshimasa, Nosé, Masahito, Nagatsuma, Tsutomu, Nishitani, Nozomu, Kadokura, Akira, Connors, Martin, Inoue, Takumi, Matsuoka, Ayako, Shinohara, Iku, 80342616, 90785495, 80270437, Ozaki, Mitsunori, Miyoshi, Yoshizumi, Shiokawa, Kazuo, Hosokawa, Keisuke, Oyama, Shin-ichiro, Kataoka, Ryuho, Ebihara, Yusuke, Ogawa, Yasunobu, Kasahara, Yoshiya, Yagitani, Satoshi, Kasaba, Yasumasa, Kumamoto, Atsushi, Tsuchiya, Fuminori, Matsuda, Shoya, Katoh, Yuto, Hikishima, Mitsuru, Kurita, Satoshi, Otsuka, Yuichi, Moore, Robert C., Tanaka, Yoshimasa, Nosé, Masahito, Nagatsuma, Tsutomu, Nishitani, Nozomu, Kadokura, Akira, Connors, Martin, Inoue, Takumi, Matsuoka, Ayako, and Shinohara, 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

16. Active auroral arc powered by accelerated electrons from very high altitudes.

Author

Imajo, Shun, Miyoshi, Yoshizumi, Kazama, Yoichi, Asamura, Kazushi, Shinohara, Iku, Shiokawa, Kazuo, Kasahara, Yoshiya, Kasaba, Yasumasa, Matsuoka, Ayako, Wang, Shiang-Yu, Tam, Sunny W. Y., Chang, Tzu‑Fang, Wang, Bo‑Jhou, Angelopoulos, Vassilis, Jun, Chae-Woo, Shoji, Masafumi, Nakamura, Satoko, Kitahara, Masahiro, Teramoto, Mariko, and Kurita, Satoshi

Subjects

ELECTRON accelerators, ELECTRIC fields, THERMOSPHERE, IONOSPHERE, MAGNETOSPHERE

Abstract

Bright, discrete, thin auroral arcs are a typical form of auroras in nightside polar regions. Their light is produced by magnetospheric electrons, accelerated downward to obtain energies of several kilo electron volts by a quasi-static electric field. These electrons collide with and excite thermosphere atoms to higher energy states at altitude of ~ 100 km; relaxation from these states produces the auroral light. The electric potential accelerating the aurora-producing electrons has been reported to lie immediately above the ionosphere, at a few altitudes of thousand kilometres1. However, the highest altitude at which the precipitating electron is accelerated by the parallel potential drop is still unclear. Here, we show that active auroral arcs are powered by electrons accelerated at altitudes reaching greater than 30,000 km. We employ high-angular resolution electron observations achieved by the Arase satellite in the magnetosphere and optical observations of the aurora from a ground-based all-sky imager. Our observations of electron properties and dynamics resemble those of electron potential acceleration reported from low-altitude satellites except that the acceleration region is much higher than previously assumed. This shows that the dominant auroral acceleration region can extend far above a few thousand kilometres, well within the magnetospheric plasma proper, suggesting formation of the acceleration region by some unknown magnetospheric mechanisms. [ABSTRACT FROM AUTHOR]

Published

2021

17. Measurements of Magnetic Field Fluctuations for Plasma Wave Investigation by the Search Coil Magnetometers (SCM) Onboard Bepicolombo Mio (Mercury Magnetospheric Orbiter).

Author

Yagitani, Satoshi, Ozaki, Mitsunori, Sahraoui, Fouad, Mirioni, Laurent, Mansour, Malik, Chanteur, Gerard, Coillot, Christophe, Ruocco, Sebastien, Leray, Vincent, Hikishima, Mitsuru, Alison, Dominique, Le Contel, Olivier, Kojima, Hirotsugu, Kasahara, Yoshiya, Kasaba, Yasumasa, Sasaki, Takashi, Yumoto, Takahiro, and Takeuchi, Yoshinari

Subjects

MAGNETIC field measurements, PLASMA waves, PARTICLE acceleration, SOLAR wind, MAGNETIC reconnection, MAGNETIC measurements, MAGNETOMETERS

Abstract

This paper describes the design and performance of the search coil magnetometers (SCM), which are part of the Plasma Wave Investigation (PWI) instrument onboard the BepiColombo/Mio spacecraft (Mercury Magnetospheric Orbiter), which will measure the electric field, plasma waves and radio waves for the first time in Mercury's plasma environment. The SCM consists of two low-frequency orthogonal search coil sensors (LF-SC) measuring two components of the magnetic field (0.1 Hz – 20 kHz) in the spacecraft spin plane, and a dual-band search coil sensor (DB-SC) picking up the third component along the spin axis at both low-frequencies (LF: 0.1 Hz – 20 kHz) and high-frequencies (HF: 10 kHz – 640 kHz). The DB-SC and the two LF-SC sensors form a tri-axial configuration at the tip of a 4.6-m coilable mast (MAST-SC) extending from the spacecraft body, to minimize artificial magnetic field contamination emitted by the spacecraft electronics. After the successful launch of the spacecraft on 20 October 2018, an initial function check for the SCM was conducted. The nominal function and performance of the sensors and preamplifiers were confirmed, even with the MAST-SC being retracted and stowed in the spacecraft body, resulting in the detection of large interference signals likely from spacecraft electronics. The MAST-SC is scheduled for deployment after the Mercury orbit insertion of Mio in 2025, allowing the SCM to make the first higher frequency measurements of magnetic fluctuations in the Hermean magnetosphere and exosphere, and the local solar wind. These measurements will contribute to the investigation of fundamental problems in the Hermean plasma environment, including turbulence, magnetic reconnection, wave-particle interactions and particle acceleration. [ABSTRACT FROM AUTHOR]

Published

2020

18. Plasma Wave Investigation (PWI) Aboard BepiColombo Mio on the Trip to the First Measurement of Electric Fields, Electromagnetic Waves, and Radio Waves Around Mercury.

Author

Kasaba, Yasumasa, Kojima, Hirotsugu, Moncuquet, Michel, Wahlund, Jan-Erik, Yagitani, Satoshi, Sahraoui, Fouad, Henri, Pierre, Karlsson, Tomas, Kasahara, Yoshiya, Kumamoto, Atsushi, Ishisaka, Keigo, Issautier, Karine, Wattieaux, Gaëtan, Imachi, Tomohiko, Matsuda, Shoya, Lichtenberger, Janos, and Usui, Hideyuki

Subjects

ELECTRIC field strength, PLASMA waves, DUSTY plasmas, RADIO waves, ELECTROMAGNETIC waves, MAGNETOHYDRODYNAMIC waves, MERCURY

Abstract

The Plasma Wave Investigation (PWI) aboard the BepiColombo Mio (Mercury Magnetospheric Orbiter, MMO) will enable the first observations of electric fields, plasma waves, and radio waves in and around the Hermean magnetosphere and exosphere. The PWI has two sets of receivers (EWO with AM2P, SORBET) connected to two electric field sensors (MEFISTO and WPT) and two magnetic field sensors (SCM: LF-SC and DB-SC). After the launch on October 20, 2018, we began initial operations, confirmed that all receivers were functioning properly, and released the launch locks on the sensors. Those sensors are not deployed during the cruising phase, but the PWI is still capable performing magnetic field observations. After full deployment of all sensors following insertion into Mercury orbit, the PWI will start its measurements of the electric field from DC to 10 MHz using two dipole antennae with a 32-m tip-to-tip length in the spin plane and the magnetic field from 0.3 Hz to 20 kHz using a three-axis sensor and from 2.5 kHz to 640 kHz using a single-axis sensor at the tip of a 4.5-m solid boom extended from the spacecraft's side panel. Those receivers and sensors will provide (1) in-situ measurements of electron density and temperature that can be used to determine the structure and dynamics of the Hermean plasma environment; (2) in-situ measurements of the electron and ion scale waves that characterize the energetic processes governed by wave–particle interactions and non-MHD interactions; (3) information on radio waves, which can be used to remotely probe solar activity in the heliocentric sector facing Mercury, to study electromagnetic-energy transport to and from Mercury, and to obtain crustal information from reflected electromagnetic waves; and (4) information concerning dust impacts on the spacecraft body detected via potential disturbances. This paper summarizes the characteristics of the overall PWI, including its significance, its objectives, its expected performance specifications, and onboard and ground data processing. This paper also presents the detailed design of the receiver components installed in a unified chassis. The PWI in the cruise phase will observe magnetic-field turbulence during multiple flybys of Earth, Venus, and Mercury. After the Mercury-orbit insertion planned at the end of 2025, we will deploy all sensors and commence full operation while coordinating with all payloads onboard the Mio and MPO spacecraft. [ABSTRACT FROM AUTHOR]

Published

2020

19. Mission Data Processor Aboard the BepiColombo Mio Spacecraft: Design and Scientific Operation Concept.

Author

Kasaba, Yasumasa, Takashima, Takeshi, Matsuda, Shoya, Eguchi, Sadatoshi, Endo, Manabu, Miyabara, Takeshi, Taeda, Masahiro, Kuroda, Yoshikatsu, Kasahara, Yoshiya, Imachi, Tomohiko, Kojima, Hirotsugu, Yagitani, Satoshi, Moncuquet, Michel, Wahlund, Jan-Erik, Kumamoto, Atsushi, Matsuoka, Ayako, Baumjohann, Wolfgang, Yokota, Shoichiro, Asamura, Kazushi, and Saito, Yoshifumi

Subjects

PLASMA sheaths, PLASMA waves, ENVIRONMENTAL sciences, RADIO waves, MAGNETIC fields, SPACE vehicles

Abstract

BepiColombo Mio, also known as the Mercury Magnetospheric Orbiter (MMO), is intended to conduct the first detailed study of the magnetic field and environment of the innermost planet, Mercury, alongside the Mercury Planetary Orbiter (MPO). This orbiter has five payload groups; the MaGnetic Field Investigation (MGF), the Mercury Plasma Particle Experiment (MPPE), the Plasma Wave Investigation (PWI), the Mercury Sodium Atmosphere Spectral Imager (MSASI), and the Mercury Dust Monitor (MDM). These payloads operate through the Mission Data Processor (MDP) that acts as an integrated system for Hermean environmental studies by the in situ observation of charged and energetic neutral particles, magnetic and electric fields, plasma waves, dust, and the remote sensing of radio waves and exospheric emissions. The MDP produces three kinds of coordinated data sets: Survey (L) mode for continuous monitoring, Nominal (M) mode for standard analyses of several hours in length (or more), and Burst (H) mode for analysis based on 4–20-min-interval datasets with the highest cadence. To utilize the limited telemetry bandwidth, nominal- and burst-mode data sets are partially downlinked after selections of data based on L- or L/M-mode data, respectively. Burst-mode data can be taken at preset timings, or by onboard automatic triggering. The MDP functions are implemented and tested on the ground as well as cruising spacecraft; they are responsible for conducting full scientific operations aboard spacecraft. [ABSTRACT FROM AUTHOR]

Published

2020

20. Onboard software of Plasma Wave Experiment aboard Arase: instrument management and signal processing of Waveform Capture/Onboard Frequency Analyzer

Author

10215254, 90785495, 80270437, Matsuda, Shoya, Kasahara, Yoshiya, Kojima, Hirotsugu, Kasaba, Yasumasa, Yagitani, Satoshi, Ozaki, Mitsunori, Imachi, Tomohiko, Ishisaka, Keigo, Kumamoto, Atsushi, Tsuchiya, Fuminori, Ota, Mamoru, Kurita, Satoshi, Miyoshi, Yoshizumi, Hikishima, Mitsuru, Matsuoka, Ayako, Shinohara, Iku, 10215254, 90785495, 80270437, Matsuda, Shoya, Kasahara, Yoshiya, Kojima, Hirotsugu, Kasaba, Yasumasa, Yagitani, Satoshi, Ozaki, Mitsunori, Imachi, Tomohiko, Ishisaka, Keigo, Kumamoto, Atsushi, Tsuchiya, Fuminori, Ota, Mamoru, Kurita, Satoshi, Miyoshi, Yoshizumi, Hikishima, Mitsuru, Matsuoka, Ayako, and Shinohara, Iku

Abstract

We developed the onboard processing software for the Plasma Wave Experiment (PWE) onboard the Exploration of energization and Radiation in Geospace, Arase satellite. The PWE instrument has three receivers: Electric Field Detector, Waveform Capture/Onboard Frequency Analyzer (WFC/OFA), and the High-Frequency Analyzer. We designed a pseudo-parallel processing scheme with a time-sharing system and achieved simultaneous signal processing for each receiver. Since electric and magnetic field signals are processed by the different CPUs, we developed a synchronized observation system by using shared packets on the mission network. The OFA continuously measures the power spectra, spectral matrices, and complex spectra. The OFA obtains not only the entire ELF/VLF plasma waves’ activity but also the detailed properties (e.g., propagation direction and polarization) of the observed plasma waves. We performed simultaneous observation of electric and magnetic field data and successfully obtained clear wave properties of whistler-mode chorus waves using these data. In order to measure raw waveforms, we developed two modes for the WFC, ‘chorus burst mode’ (65, 536 samples/s) and ‘EMIC burst mode’ (1024 samples/s), for the purpose of the measurement of the whistler-mode chorus waves (typically in a frequency range from several hundred Hz to several kHz) and the EMIC waves (typically in a frequency range from a few Hz to several hundred Hz), respectively. We successfully obtained the waveforms of electric and magnetic fields of whistler-mode chorus waves and ion cyclotron mode waves along the Arase’s orbit. We also designed the software-type wave–particle interaction analyzer mode. In this mode, we measure electric and magnetic field waveforms continuously and transfer them to the mission data recorder onboard the Arase satellite. We also installed an onboard signal calibration function (onboard SoftWare CALibration; SWCAL). We performed onboard electric circuit diagnostics and anten

Published

2018

21. Software-type Wave–Particle Interaction Analyzer on board the Arase satellite

Author

10215254, 80270437, Katoh, Yuto, Kojima, Hirotsugu, Hikishima, Mitsuru, Takashima, Takeshi, Asamura, Kazushi, Miyoshi, Yoshizumi, Kasahara, Yoshiya, Kasahara, Satoshi, Mitani, Takefumi, Higashio, Nana, Matsuoka, Ayako, Ozaki, Mitsunori, Yagitani, Satoshi, Yokota, Shoichiro, Matsuda, Shoya, Kitahara, Masahiro, Shinohara, Iku, 10215254, 80270437, Katoh, Yuto, Kojima, Hirotsugu, Hikishima, Mitsuru, Takashima, Takeshi, Asamura, Kazushi, Miyoshi, Yoshizumi, Kasahara, Yoshiya, Kasahara, Satoshi, Mitani, Takefumi, Higashio, Nana, Matsuoka, Ayako, Ozaki, Mitsunori, Yagitani, Satoshi, Yokota, Shoichiro, Matsuda, Shoya, Kitahara, Masahiro, and Shinohara, Iku

Published

2018

22. Magnetic Search Coil (MSC) of Plasma Wave Experiment (PWE) aboard the Arase (ERG) satellite

Author

10215254, 80270437, Ozaki, Mitsunori, Yagitani, Satoshi, Kasahara, Yoshiya, Kojima, Hirotsugu, Kasaba, Yasumasa, Kumamoto, Atsushi, Tsuchiya, Fuminori, Matsuda, Shoya, Matsuoka, Ayako, Sasaki, Takashi, Yumoto, Takahiro, 10215254, 80270437, Ozaki, Mitsunori, Yagitani, Satoshi, Kasahara, Yoshiya, Kojima, Hirotsugu, Kasaba, Yasumasa, Kumamoto, Atsushi, Tsuchiya, Fuminori, Matsuda, Shoya, Matsuoka, Ayako, Sasaki, Takashi, and Yumoto, Takahiro

Abstract

This paper presents detailed performance values of the Magnetic Search Coil (MSC) that is part of the Plasma Wave Experiment on board the Arase (ERG) satellite. The MSC consists of a three-axis search coil magnetometer with a 200-mm-long magnetic core. The MSC plays a central role in the magnetic field observations, particularly for whistler mode chorus and hiss waves in a few kHz frequency range, which may cause local acceleration and/or rapid loss of radiation belt electrons. Accordingly, the MSC was carefully designed and developed to operate well in harsh radiation environments. To ascertain the wave-normal vectors, polarizations, and refractive indices of the plasma waves in a wide frequency band, the output signals detected by the MSC are fed into the two different wave receivers: one is the WaveForm Capture/Onboard Frequency Analyzer for waveform and spectrum observations in the frequency range from a few Hz up to 20 kHz, and the other is the High Frequency Analyzer for spectrum observations in the frequency range from 10 to 100 kHz. The noise equivalent magnetic induction of the MSC is 20 fT/Hz¹/² at a frequency of 2 kHz, and the null depth of directionality is − 40 dB, which is equivalent to an angular error less than 1°. The MSC on board the Arase satellite is the first experiment using a current-sensitive preamplifier for probing the plasma waves in the radiation belts.

Published

2018

23. The Plasma Wave Experiment (PWE) on board the Arase (ERG) satellite

Author

10215254, 80270437, Kasahara, Yoshiya, Kasaba, Yasumasa, Kojima, Hirotsugu, Yagitani, Satoshi, Ishisaka, Keigo, Kumamoto, Atsushi, Tsuchiya, Fuminori, Ozaki, Mitsunori, Matsuda, Shoya, Imachi, Tomohiko, Miyoshi, Yoshizumi, Hikishima, Mitsuru, Katoh, Yuto, Ota, Mamoru, Shoji, Masafumi, Matsuoka, Ayako, Shinohara, Iku, 10215254, 80270437, Kasahara, Yoshiya, Kasaba, Yasumasa, Kojima, Hirotsugu, Yagitani, Satoshi, Ishisaka, Keigo, Kumamoto, Atsushi, Tsuchiya, Fuminori, Ozaki, Mitsunori, Matsuda, Shoya, Imachi, Tomohiko, Miyoshi, Yoshizumi, Hikishima, Mitsuru, Katoh, Yuto, Ota, Mamoru, Shoji, Masafumi, Matsuoka, Ayako, and Shinohara, Iku

Abstract

The Exploration of energization and Radiation in Geospace (ERG) project aims to study acceleration and loss mechanisms of relativistic electrons around the Earth. The Arase (ERG) satellite was launched on December 20, 2016, to explore in the heart of the Earth’s radiation belt. In the present paper, we introduce the specifications of the Plasma Wave Experiment (PWE) on board the Arase satellite. In the inner magnetosphere, plasma waves, such as the whistler-mode chorus, electromagnetic ion cyclotron wave, and magnetosonic wave, are expected to interact with particles over a wide energy range and contribute to high-energy particle loss and/or acceleration processes. Thermal plasma density is another key parameter because it controls the dispersion relation of plasma waves, which affects wave–particle interaction conditions and wave propagation characteristics. The DC electric field also plays an important role in controlling the global dynamics of the inner magnetosphere. The PWE, which consists of an orthogonal electric field sensor (WPT; wire probe antenna), a triaxial magnetic sensor (MSC; magnetic search coil), and receivers named electric field detector (EFD), waveform capture and onboard frequency analyzer (WFC/OFA), and high-frequency analyzer (HFA), was developed to measure the DC electric field and plasma waves in the inner magnetosphere. Using these sensors and receivers, the PWE covers a wide frequency range from DC to 10 MHz for electric fields and from a few Hz to 100 kHz for magnetic fields. We produce continuous ELF/VLF/HF range wave spectra and ELF range waveforms for 24 h each day. We also produce spectral matrices as continuous data for wave direction finding. In addition, we intermittently produce two types of waveform burst data, “chorus burst” and “EMIC burst.” We also input raw waveform data into the software-type wave–particle interaction analyzer (S-WPIA), which derives direct correlation between waves and particles. Finally, we introduce our

Published

2018

24. Data processing in Software-type Wave–Particle Interaction Analyzer onboard the Arase satellite

Author

10215254, 80270437, Hikishima, Mitsuru, Kojima, Hirotsugu, Katoh, Yuto, Kasahara, Yoshiya, Kasahara, Satoshi, Mitani, Takefumi, Higashio, Nana, Matsuoka, Ayako, Miyoshi, Yoshizumi, Asamura, Kazushi, Takashima, Takeshi, Yokota, Shoichiro, Kitahara, Masahiro, Matsuda, Shoya, 10215254, 80270437, Hikishima, Mitsuru, Kojima, Hirotsugu, Katoh, Yuto, Kasahara, Yoshiya, Kasahara, Satoshi, Mitani, Takefumi, Higashio, Nana, Matsuoka, Ayako, Miyoshi, Yoshizumi, Asamura, Kazushi, Takashima, Takeshi, Yokota, Shoichiro, Kitahara, Masahiro, and Matsuda, Shoya

Abstract

The software-type wave–particle interaction analyzer (S-WPIA) is an instrument package onboard the Arase satellite, which studies the magnetosphere. The S-WPIA represents a new method for directly observing wave–particle interactions onboard a spacecraft in a space plasma environment. The main objective of the S-WPIA is to quantitatively detect wave–particle interactions associated with whistler-mode chorus emissions and electrons over a wide energy range (from several keV to several MeV). The quantity of energy exchanges between waves and particles can be represented as the inner product of the wave electric-field vector and the particle velocity vector. The S-WPIA requires accurate measurement of the phase difference between wave and particle gyration. The leading edge of the S-WPIA system allows us to collect comprehensive information, including the detection time, energy, and incoming direction of individual particles and instantaneous-wave electric and magnetic fields, at a high sampling rate. All the collected particle and waveform data are stored in the onboard large-volume data storage. The S-WPIA executes calculations asynchronously using the collected electric and magnetic wave data, data acquired from multiple particle instruments, and ambient magnetic-field data. The S-WPIA has the role of handling large amounts of raw data that are dedicated to calculations of the S-WPIA. Then, the results are transferred to the ground station. This paper describes the design of the S-WPIA and its calculations in detail, as implemented onboard Arase.

Published

2018

25. High Frequency Analyzer (HFA) of Plasma Wave Experiment (PWE) onboard the Arase spacecraft

Author

10215254, Kumamoto, Atsushi, Tsuchiya, Fuminori, Kasahara, Yoshiya, Kasaba, Yasumasa, Kojima, Hirotsugu, Yagitani, Satoshi, Ishisaka, Keigo, Imachi, Tomohiko, Ozaki, Mitsunori, Matsuda, Shoya, Shoji, Masafumi, Matsuoka, Aayako, Katoh, Yuto, Miyoshi, Yoshizumi, Obara, Takahiro, 10215254, Kumamoto, Atsushi, Tsuchiya, Fuminori, Kasahara, Yoshiya, Kasaba, Yasumasa, Kojima, Hirotsugu, Yagitani, Satoshi, Ishisaka, Keigo, Imachi, Tomohiko, Ozaki, Mitsunori, Matsuda, Shoya, Shoji, Masafumi, Matsuoka, Aayako, Katoh, Yuto, Miyoshi, Yoshizumi, and Obara, Takahiro

Abstract

The High Frequency Analyzer (HFA) is a subsystem of the Plasma Wave Experiment onboard the Arase (ERG) spacecraft. The main purposes of the HFA include (1) determining the electron number density around the spacecraft from observations of upper hybrid resonance (UHR) waves, (2) measuring the electromagnetic field component of whistler-mode chorus in a frequency range above 20 kHz, and (3) observing radio and plasma waves excited in the storm-time magnetosphere. Two components of AC electric fields detected by Wire Probe Antenna and one component of AC magnetic fields detected by Magnetic Search Coils are fed to the HFA. By applying analog and digital signal processing in the HFA, the spectrograms of two electric fields (EE mode) or one electric field and one magnetic field (EB mode) in a frequency range from 10 kHz to 10 MHz are obtained at an interval of 8 s. For the observation of plasmapause, the HFA can also be operated in PP (plasmapause) mode, in which spectrograms of one electric field component below 1 MHz are obtained at an interval of 1 s. In the initial HFA operations from January to July, 2017, the following results are obtained: (1) UHR waves, auroral kilometric radiation (AKR), whistler-mode chorus, electrostatic electron cyclotron harmonic waves, and nonthermal terrestrial continuum radiation were observed by the HFA in geomagnetically quiet and disturbed conditions. (2) In the test operations of the polarization observations on June 10, 2017, the fundamental R-X and L-O mode AKR and the second-harmonic R-X mode AKR from different sources in the northern polar region were observed. (3) The semiautomatic UHR frequency identification by the computer and a human operator was applied to the HFA spectrograms. In the identification by the computer, we used an algorithm for narrowing down the candidates of UHR frequency by checking intensity and bandwidth. Then, the identified UHR frequency by the computer was checked and corrected if needed by the human ope

Published

2018

26. Pulsating aurora from electron scattering by chorus waves

Author

Kasahara, Satoshi, Miyoshi, Yoshizumi, Yokota, Shoichiro, Mitani, Takefumi, Kasahara, Yoshiya, Matsuda, Shoya, Kumamoto, Atsushi, Matsuoka, Ayako, Kazama, Yoichi, Frey, H. U., Angelopoulos, V., Kurita, Satoshi, Keika, Kunihiro, Seki, Kanako, Shinohara, Iku, 笠原, 慧, 三好, 由純, 横田, 勝一郎, 三谷, 烈史, 笠原, 禎也, 松田, 昇也, 熊本, 篤志, 松岡, 彩子, 風間, 洋一, 栗田, 怜, 桂華, 邦裕, 関, 華奈子, 篠原, 育, Kasahara, Satoshi, Miyoshi, Yoshizumi, Yokota, Shoichiro, Mitani, Takefumi, Kasahara, Yoshiya, Matsuda, Shoya, Kumamoto, Atsushi, Matsuoka, Ayako, Kazama, Yoichi, Frey, H. U., Angelopoulos, V., Kurita, Satoshi, Keika, Kunihiro, Seki, Kanako, Shinohara, Iku, 笠原, 慧, 三好, 由純, 横田, 勝一郎, 三谷, 烈史, 笠原, 禎也, 松田, 昇也, 熊本, 篤志, 松岡, 彩子, 風間, 洋一, 栗田, 怜, 桂華, 邦裕, 関, 華奈子, and 篠原, 育

Abstract

著者人数: 15名, Accepted: 2017-12-21

Published

2018

27. Software-type Wave-Particle Interaction Analyzer on board the Arase satellite.

Author

Katoh, Yuto, Kojima, Hirotsugu, Hikishima, Mitsuru, Takashima, Takeshi, Asamura, Kazushi, Miyoshi, Yoshizumi, Kasahara, Yoshiya, Kasahara, Satoshi, Mitani, Takefumi, Higashio, Nana, Matsuoka, Ayako, Ozaki, Mitsunori, Yagitani, Satoshi, Yokota, Shoichiro, Matsuda, Shoya, Kitahara, Masahiro, and Shinohara, Iku

Subjects

WAVE-particle interactions, ARTIFICIAL satellites, HIGH energy electron diffraction, MAGNETOSPHERE, EMISSION spectroscopy

Abstract

We describe the principles of the Wave-Particle Interaction Analyzer (WPIA) and the implementation of the Software-type WPIA (S-WPIA) on the Arase satellite. The WPIA is a new type of instrument for the direct and quantitative measurement of wave-particle interactions. The S-WPIA is installed on the Arase satellite as a software function running on the mission data processor. The S-WPIA on board the Arase satellite uses an electromagnetic field waveform that is measured by the waveform capture receiver of the plasma wave experiment (PWE), and the velocity vectors of electrons detected by the medium-energy particle experiment-electron analyzer (MEP-e), the high-energy electron experiment (HEP), and the extremely high-energy electron experiment (XEP). The prime objective of the S-WPIA is to measure the energy exchange between whistler-mode chorus emissions and energetic electrons in the inner magnetosphere. It is essential for the S-WPIA to synchronize instruments to a relative time accuracy better than the time period of the plasma wave oscillations. Since the typical frequency of chorus emissions in the inner magnetosphere is a few kHz, a relative time accuracy of better than 10 μs is required in order to measure the relative phase angle between the wave and velocity vectors. In the Arase satellite, a dedicated system has been developed to realize the time resolution required for inter-instrument communication. Here, both the time index distributed over all instruments through the satellite system and an S-WPIA clock signal are used, that are distributed from the PWE to the MEP-e, HEP, and XEP through a direct line, for the synchronization of instruments within a relative time accuracy of a few μs. We also estimate the number of particles required to obtain statistically significant results with the S-WPIA and the expected accumulation time by referring to the specifications of the MEP-e and assuming a count rate for each detector. [ABSTRACT FROM AUTHOR]

Published

2018

28. Wire Probe Antenna (WPT) and Electric Field Detector (EFD) of Plasma Wave Experiment (PWE) aboard the Arase satellite: specifications and initial evaluation results.

Author

Kasaba, Yasumasa, Ishisaka, Keigo, Kasahara, Yoshiya, Imachi, Tomohiko, Yagitani, Satoshi, Kojima, Hirotsugu, Matsuda, Shoya, Shoji, Masafumi, Kurita, Satoshi, Hori, Tomoaki, Shinbori, Atsuki, Teramoto, Mariko, Miyoshi, Yoshizumi, Nakagawa, Tomoko, Takahashi, Naoko, Nishimura, Yukitoshi, Matsuoka, Ayako, Kumamoto, Atsushi, Tsuchiya, Fuminori, and Nomura, Reiko

Subjects

ANTENNAS (Electronics), ELECTRIC fields, PLASMA waves, ELECTROMAGNETIC waves, IONS

Abstract

This paper summarizes the specifications and initial evaluation results of Wire Probe Antenna (WPT) and Electric Field Detector (EFD), the key components for the electric field measurement of the Plasma Wave Experiment (PWE) aboard the Arase (ERG) satellite. WPT consists of two pairs of dipole antennas with ~ 31-m tip-to-tip length. Each antenna element has a spherical probe (60 mm diameter) at each end of the wire (15 m length). They are extended orthogonally in the spin plane of the spacecraft, which is roughly perpendicular to the Sun and enables to measure the electric field in the frequency range of DC to 10 MHz. This system is almost identical to the WPT of Plasma Wave Investigation aboard the BepiColombo Mercury Magnetospheric Orbiter, except for the material of the spherical probe (ERG: Al alloy, MMO: Ti alloy). EFD is a part of the EWO (EFD/WFC/OFA) receiver and measures the 2-ch electric field at a sampling rate of 512 Hz (dynamic range: ± 200 mV/m) and the 4-ch spacecraft potential at a sampling rate of 128 Hz (dynamic range: ± 100 V and ± 3 V/m), with the bias control capability of WPT. The electric field waveform provides (1) fundamental information about the plasma dynamics and accelerations and (2) the characteristics of MHD and ion waves in various magnetospheric statuses with the magnetic field measured by MGF and PWE-MSC. The spacecraft potential provides information on thermal electron plasma variations and structure combined with the electron density obtained from the upper hybrid resonance frequency provided by PWE-HFA. EFD has two data modes. The continuous (medium-mode) data are provided as (1) 2-ch waveforms at 64 Hz (in apoapsis mode, L > 4) or 256 Hz (in periapsis mode, L < 4), (2) 1-ch spectrum within 1-232 Hz with 1-s resolution, and (3) 4-ch spacecraft potential at 8 Hz. The burst (high-mode) data are intermittently obtained as (4) 2-ch waveforms at 512 Hz and (5) 4-ch spacecraft potential at 128 Hz and downloaded with the WFC-E/B datasets after the selection. This paper also shows the initial evaluation results in the initial observation phase. [ABSTRACT FROM AUTHOR]

Published

2017

29. Statistical study on propagation characteristics of Omega signals (VLF) in magnetosphere detected by the Akebono satellite.

Author

Suarjaya, I, Kasahara, Yoshiya, and Goto, Yoshitaka

Subjects

*MAGNETOSPHERE, *ELECTRON density, *SOLAR activity, *SOLAR radiation, *PLASMASPHERE, *ARTIFICIAL satellites

Abstract

This paper shows a statistical analysis of 10.2 kHz Omega broadcasts of an artificial signal broadcast from ground stations, propagated in the plasmasphere, and detected using an automatic detection method we developed. We study the propagation patterns of the Omega signals to understand the propagation characteristics that are strongly affected by plasmaspheric electron density and the ambient magnetic field. We show the unique propagation patterns of the Omega 10.2 kHz signal when it was broadcast from two high-middle-latitude stations. We use about eight years of data captured by the Poynting flux analyzer subsystem on board the Akebono satellite from October 1989 to September 1997. We demonstrate that the signals broadcast from almost the same latitude (in geomagnetic coordinates) propagated differently depending on the geographic latitude. We also study propagation characteristics as a function of local time, season, and solar activity. The Omega signal tended to propagate farther on the nightside than on the dayside and was more widely distributed during winter than during summer. When solar activity was at maximum, the Omega signal propagated at a lower intensity level. In contrast, when solar activity was at minimum, the Omega signal propagated at a higher intensity and farther from the transmitter station. [ABSTRACT FROM AUTHOR]

Published

2017

30. Correction to: ISEE_Wave: interactive plasma wave analysis tool.

Author

Matsuda, Shoya, Miyoshi, Yoshizumi, Nakamura, Satoko, Kitahara, Masahiro, Shoji, Masafumi, Hori, Tomoaki, Imajo, Shun, Jun, Chae-Woo, Kurita, Satoshi, Kasahara, Yoshiya, Matsuoka, Ayako, and Shinohara, Iku

Subjects

WAVE analysis, EARTH (Planet)

Abstract

Correction to: Earth Planets Space (2021) 73:110 https://doi.org/10.1186/s40623-021-01430-3 After publication of this article (Matsuda et al. [1]), it is noticed the 8th author's name is incorrect. Reference 1 Matsuda S, Miyoshi Y, Nakamura S, Kitahara M, Shoji M, Hori T, Imajo S, Jun C-W, Kurita S, Kasahara Y, Matsuoka A, Shinohara I. ISEE Wave: interactive plasma wave analysis tool. Correction to: ISEE Wave: interactive plasma wave analysis tool. [Extracted from the article]

Published

2021

31. Transient ionization of the mesosphere during auroral breakup: Arase satellite and ground-based conjugate observations at Syowa Station.

Author

Kataoka, Ryuho, Nishiyama, Takanori, Tanaka, Yoshimasa, Kadokura, Akira, Uchida, Herbert Akihito, Ebihara, Yusuke, Ejiri, Mitsumu K., Tomikawa, Yoshihiro, Tsutsumi, Masaki, Sato, Kaoru, Miyoshi, Yoshizumi, Shiokawa, Kazuo, Kurita, Satoshi, Kasahara, Yoshiya, Ozaki, Mitsunori, Hosokawa, Keisuke, Matsuda, Shoya, Shinohara, Iku, Takashima, Takeshi, and Sato, Tatsuhiko

Subjects

ATMOSPHERIC ionization, MESOSPHERE, NATURAL satellites, COSMIC noise, METEOROLOGICAL precipitation, MONTE Carlo method, AURORAL electrons

Abstract

Transient mesospheric echo in the VHF range was detected at an altitude of 65-70 km during the auroral breakup that occurred from 2220 to 2226 UT on June 30, 2017. During this event, the footprint of the Arase satellite was located within the field of view of the all-sky imagers at Syowa Station in the Antarctic. Auroral observations at Syowa Station revealed the dominant precipitation of relatively soft electrons during the auroral breakup. A corresponding spike in cosmic noise absorption was also observed at Syowa Station, while the Arase satellite observed a flux enhancement of > 100 keV electrons and a broadband noise without detecting chorus waves or electromagnetic ion cyclotron waves. A general-purpose Monte Carlo particle transport simulation code was used to quantitatively evaluate the ionization in the middle atmosphere. Results of this study indicate that the precipitation of energetic electrons of > 100 keV, rather than X-rays from the auroral electrons, played a dominant role in the transient and deep (65-70 km) mesospheric ionization during the observed auroral breakup. [ABSTRACT FROM AUTHOR]

Published

2019

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

Author

Ozaki, Mitsunori, Miyoshi, Yoshizumi, Shiokawa, Kazuo, Hosokawa, Keisuke, Oyama, Shin-ichiro, Kataoka, Ryuho, Ebihara, Yusuke, Ogawa, Yasunobu, Kasahara, Yoshiya, Yagitani, Satoshi, Kasaba, Yasumasa, Kumamoto, Atsushi, Tsuchiya, Fuminori, Matsuda, Shoya, Katoh, Yuto, Hikishima, Mitsuru, Kurita, Satoshi, Otsuka, Yuichi, Moore, Robert C., and Tanaka, Yoshimasa

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. Electron precipitation plays major role in magnetospheric physics and space weather. Here the authors show nonlinear behavior of the wave-particle interaction in the magnetosphere as the evolution of chorus electromagnetic waves detected by the Arase satellite and PWING observatory. [ABSTRACT FROM AUTHOR]

Published

2019

33. Geospace exploration project ERG.

Author

Miyoshi, Yoshizumi, Shinohara, Iku, Takashima, Takeshi, Asamura, Kazushi, Higashio, Nana, Mitani, Takefumi, Kasahara, Satoshi, Yokota, Shoichiro, Kazama, Yoichi, Wang, Shiang-Yu, Tam, Sunny W. Y., Ho, Paul T. P., Kasahara, Yoshiya, Kasaba, Yasumasa, Yagitani, Satoshi, Matsuoka, Ayako, Kojima, Hirotsugu, Katoh, Yuto, Shiokawa, Kazuo, and Seki, Kanako

Subjects

ELECTRONS, RADIATION, COSMIC rays, PLASMA gases, MAGNETIC fields

Abstract

The Exploration of energization and Radiation in Geospace (ERG) project explores the acceleration, transport, and loss of relativistic electrons in the radiation belts and the dynamics for geospace storms. This project consists of three research teams for satellite observation, ground-based network observation, and integrated data analysis/simulation. This synergetic approach is essential for obtaining a comprehensive understanding of the relativistic electron generation/loss processes of the radiation belts as well as geospace storms through cross-energy/cross-regional couplings, in which different plasma/particle populations and regions are strongly coupled with each other. This paper gives an overview of the ERG project and presents the initial results from the ERG (Arase) satellite. [ABSTRACT FROM AUTHOR]

Published

2018

34. The ERG Science Center.

Author

Miyoshi, Yoshizumi, Hori, Tomoaki, Shoji, Masafumi, Teramoto, Mariko, Chang, T. F., Segawa, Tomonori, Umemura, Norio, Matsuda, Shoya, Kurita, Satoshi, Keika, Kunihiro, Miyashita, Yukinaga, Seki, Kanako, Tanaka, Yoshimasa, Nishitani, Nozomu, Kasahara, Satoshi, Yokota, Shoichiro, Matsuoka, Ayako, Kasahara, Yoshiya, Asamura, Kazushi, and Takashima, Takeshi

Subjects

DATA analysis software, NATURAL satellites, RADIATION, SCIENCE museums, ARTIFICIAL satellites

Abstract

The Exploration of energization and Radiation in Geospace (ERG) Science Center serves as a hub of the ERG project, providing data files in a common format and developing the space physics environment data analysis software and plug-ins for data analysis. The Science Center also develops observation plans for the ERG (Arase) satellite according to the science strategy of the project. Conjugate observations with other satellites and ground-based observations are also planned. These tasks contribute to the ERG project by achieving quick analysis and well-organized conjugate ERG satellite and ground-based observations. [ABSTRACT FROM AUTHOR]

Published

2018

35. The Plasma Wave Experiment (PWE) on board the Arase (ERG) satellite.

Author

Kasahara, Yoshiya, Kasaba, Yasumasa, Kojima, Hirotsugu, Yagitani, Satoshi, Ishisaka, Keigo, Kumamoto, Atsushi, Tsuchiya, Fuminori, Ozaki, Mitsunori, Matsuda, Shoya, Imachi, Tomohiko, Miyoshi, Yoshizumi, Hikishima, Mitsuru, Katoh, Yuto, Ota, Mamoru, Shoji, Masafumi, Matsuoka, Ayako, and Shinohara, Iku

Subjects

*SPACE plasmas, *PLASMA gases, *ELECTROMAGNETISM, *WAVE analysis, *MAGNETOSPHERE

Abstract

The Exploration of energization and Radiation in Geospace (ERG) project aims to study acceleration and loss mechanisms of relativistic electrons around the Earth. The Arase (ERG) satellite was launched on December 20, 2016, to explore in the heart of the Earth’s radiation belt. In the present paper, we introduce the specifications of the Plasma Wave Experiment (PWE) on board the Arase satellite. In the inner magnetosphere, plasma waves, such as the whistler-mode chorus, electromagnetic ion cyclotron wave, and magnetosonic wave, are expected to interact with particles over a wide energy range and contribute to high-energy particle loss and/or acceleration processes. Thermal plasma density is another key parameter because it controls the dispersion relation of plasma waves, which affects wave-particle interaction conditions and wave propagation characteristics. The DC electric field also plays an important role in controlling the global dynamics of the inner magnetosphere. The PWE, which consists of an orthogonal electric field sensor (WPT; wire probe antenna), a triaxial magnetic sensor (MSC; magnetic search coil), and receivers named electric field detector (EFD), waveform capture and onboard frequency analyzer (WFC/OFA), and high-frequency analyzer (HFA), was developed to measure the DC electric field and plasma waves in the inner magnetosphere. Using these sensors and receivers, the PWE covers a wide frequency range from DC to 10 MHz for electric fields and from a few Hz to 100 kHz for magnetic fields. We produce continuous ELF/VLF/HF range wave spectra and ELF range waveforms for 24 h each day. We also produce spectral matrices as continuous data for wave direction finding. In addition, we intermittently produce two types of waveform burst data, “chorus burst” and “EMIC burst.” We also input raw waveform data into the software-type wave-particle interaction analyzer (S-WPIA), which derives direct correlation between waves and particles. Finally, we introduce our PWE observation strategy and provide some initial results. [ABSTRACT FROM AUTHOR]

Published

2018

36. High Frequency Analyzer (HFA) of Plasma Wave Experiment (PWE) onboard the Arase spacecraft.

Author

Kumamoto, Atsushi, Tsuchiya, Fuminori, Kasahara, Yoshiya, Kasaba, Yasumasa, Kojima, Hirotsugu, Yagitani, Satoshi, Ishisaka, Keigo, Imachi, Tomohiko, Ozaki, Mitsunori, Matsuda, Shoya, Shoji, Masafumi, Matsuoka, Aayako, Katoh, Yuto, Miyoshi, Yoshizumi, and Obara, Takahiro

Subjects

PLASMA waves, SPACE vehicles, WAVE analyzers, ELECTROMAGNETIC fields, ELECTRON density, MAGNETOSPHERE

Abstract

The High Frequency Analyzer (HFA) is a subsystem of the Plasma Wave Experiment onboard the Arase (ERG) spacecraft. The main purposes of the HFA include (1) determining the electron number density around the spacecraft from observations of upper hybrid resonance (UHR) waves, (2) measuring the electromagnetic field component of whistler-mode chorus in a frequency range above 20 kHz, and (3) observing radio and plasma waves excited in the storm-time magnetosphere. Two components of AC electric fields detected by Wire Probe Antenna and one component of AC magnetic fields detected by Magnetic Search Coils are fed to the HFA. By applying analog and digital signal processing in the HFA, the spectrograms of two electric fields (EE mode) or one electric field and one magnetic field (EB mode) in a frequency range from 10 kHz to 10 MHz are obtained at an interval of 8 s. For the observation of plasmapause, the HFA can also be operated in PP (plasmapause) mode, in which spectrograms of one electric field component below 1 MHz are obtained at an interval of 1 s. In the initial HFA operations from January to July, 2017, the following results are obtained: (1) UHR waves, auroral kilometric radiation (AKR), whistler-mode chorus, electrostatic electron cyclotron harmonic waves, and nonthermal terrestrial continuum radiation were observed by the HFA in geomagnetically quiet and disturbed conditions. (2) In the test operations of the polarization observations on June 10, 2017, the fundamental R-X and L-O mode AKR and the second-harmonic R-X mode AKR from different sources in the northern polar region were observed. (3) The semiautomatic UHR frequency identification by the computer and a human operator was applied to the HFA spectrograms. In the identification by the computer, we used an algorithm for narrowing down the candidates of UHR frequency by checking intensity and bandwidth. Then, the identified UHR frequency by the computer was checked and corrected if needed by the human operator. Electron number density derived from the determined UHR frequency will be useful for the investigation of the storm-time evolution of the plasmasphere and topside ionosphere. [ABSTRACT FROM AUTHOR]

Published

2018

37. Data processing in Software-type Wave-Particle Interaction Analyzer onboard the Arase satellite.

Author

Hikishima, Mitsuru, Kojima, Hirotsugu, Katoh, Yuto, Kasahara, Yoshiya, Kasahara, Satoshi, Mitani, Takefumi, Higashio, Nana, Matsuoka, Ayako, Miyoshi, Yoshizumi, Asamura, Kazushi, Takashima, Takeshi, Yokota, Shoichiro, Kitahara, Masahiro, and Matsuda, Shoya

Subjects

PUNCHED card systems, PARTICLE interactions, ELECTRONS, EMISSIONS (Air pollution), PARTICULATE matter

Abstract

The software-type wave-particle interaction analyzer (S-WPIA) is an instrument package onboard the Arase satellite, which studies the magnetosphere. The S-WPIA represents a new method for directly observing wave-particle interactions onboard a spacecraft in a space plasma environment. The main objective of the S-WPIA is to quantitatively detect wave-particle interactions associated with whistler-mode chorus emissions and electrons over a wide energy range (from several keV to several MeV). The quantity of energy exchanges between waves and particles can be represented as the inner product of the wave electric-field vector and the particle velocity vector. The S-WPIA requires accurate measurement of the phase difference between wave and particle gyration. The leading edge of the S-WPIA system allows us to collect comprehensive information, including the detection time, energy, and incoming direction of individual particles and instantaneous-wave electric and magnetic fields, at a high sampling rate. All the collected particle and waveform data are stored in the onboard large-volume data storage. The S-WPIA executes calculations asynchronously using the collected electric and magnetic wave data, data acquired from multiple particle instruments, and ambient magnetic-field data. The S-WPIA has the role of handling large amounts of raw data that are dedicated to calculations of the S-WPIA. Then, the results are transferred to the ground station. This paper describes the design of the S-WPIA and its calculations in detail, as implemented onboard Arase. [ABSTRACT FROM AUTHOR]

Published

2018

38. Onboard software of Plasma Wave Experiment aboard Arase: instrument management and signal processing of Waveform Capture/Onboard Frequency Analyzer.

Author

Matsuda, Shoya, Kasahara, Yoshiya, Kojima, Hirotsugu, Kasaba, Yasumasa, Yagitani, Satoshi, Ozaki, Mitsunori, Imachi, Tomohiko, Ishisaka, Keigo, Kumamoto, Atsushi, Tsuchiya, Fuminori, Ota, Mamoru, Kurita, Satoshi, Miyoshi, Yoshizumi, Hikishima, Mitsuru, Matsuoka, Ayako, and Shinohara, Iku

Subjects

*PLASMA waves, *SIGNAL processing, *MAGNETIC fields, *ELECTRIC fields, *CYCLOTRON resonance

Abstract

We developed the onboard processing software for the Plasma Wave Experiment (PWE) onboard the Exploration of energization and Radiation in Geospace, Arase satellite. The PWE instrument has three receivers: Electric Field Detector, Waveform Capture/Onboard Frequency Analyzer (WFC/OFA), and the High-Frequency Analyzer. We designed a pseudo-parallel processing scheme with a time-sharing system and achieved simultaneous signal processing for each receiver. Since electric and magnetic field signals are processed by the different CPUs, we developed a synchronized observation system by using shared packets on the mission network. The OFA continuously measures the power spectra, spectral matrices, and complex spectra. The OFA obtains not only the entire ELF/VLF plasma waves’ activity but also the detailed properties (e.g., propagation direction and polarization) of the observed plasma waves. We performed simultaneous observation of electric and magnetic field data and successfully obtained clear wave properties of whistler-mode chorus waves using these data. In order to measure raw waveforms, we developed two modes for the WFC, ‘chorus burst mode’ (65,536 samples/s) and ‘EMIC burst mode’ (1024 samples/s), for the purpose of the measurement of the whistler-mode chorus waves (typically in a frequency range from several hundred Hz to several kHz) and the EMIC waves (typically in a frequency range from a few Hz to several hundred Hz), respectively. We successfully obtained the waveforms of electric and magnetic fields of whistler-mode chorus waves and ion cyclotron mode waves along the Arase’s orbit. We also designed the software-type wave-particle interaction analyzer mode. In this mode, we measure electric and magnetic field waveforms continuously and transfer them to the mission data recorder onboard the Arase satellite. We also installed an onboard signal calibration function (onboard SoftWare CALibration; SWCAL). We performed onboard electric circuit diagnostics and antenna impedance measurement of the wire-probe antennas along the orbit. We utilize the results obtained using the SWCAL function when we calibrate the spectra and waveforms obtained by the PWE. [ABSTRACT FROM AUTHOR]

Published

2018

39. Magnetic Search Coil (MSC) of Plasma Wave Experiment (PWE) aboard the Arase (ERG) satellite.

Author

Ozaki, Mitsunori, Yagitani, Satoshi, Kasahara, Yoshiya, Kojima, Hirotsugu, Kasaba, Yasumasa, Kumamoto, Atsushi, Tsuchiya, Fuminori, Matsuda, Shoya, Matsuoka, Ayako, Sasaki, Takashi, and Yumoto, Takahiro

Subjects

PLASMA waves, MAGNETOMETERS, RADIATION belts, MAGNETIC storms, PARTICLE interactions

Abstract

This paper presents detailed performance values of the Magnetic Search Coil (MSC) that is part of the Plasma Wave Experiment on board the Arase (ERG) satellite. The MSC consists of a three-axis search coil magnetometer with a 200-mm-long magnetic core. The MSC plays a central role in the magnetic field observations, particularly for whistler mode chorus and hiss waves in a few kHz frequency range, which may cause local acceleration and/or rapid loss of radiation belt electrons. Accordingly, the MSC was carefully designed and developed to operate well in harsh radiation environments. To ascertain the wave-normal vectors, polarizations, and refractive indices of the plasma waves in a wide frequency band, the output signals detected by the MSC are fed into the two different wave receivers: one is the WaveForm Capture/Onboard Frequency Analyzer for waveform and spectrum observations in the frequency range from a few Hz up to 20 kHz, and the other is the High Frequency Analyzer for spectrum observations in the frequency range from 10 to 100 kHz. The noise equivalent magnetic induction of the MSC is 20fT/Hz1/2 at a frequency of 2 kHz, and the null depth of directionality is − 40 dB, which is equivalent to an angular error less than 1∘. The MSC on board the Arase satellite is the first experiment using a current-sensitive preamplifier for probing the plasma waves in the radiation belts. [ABSTRACT FROM AUTHOR]

Published

2018