Your search keyword '"Kasaba, Yasumasa"' showing total 17 results

1. 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

Published

2020

2. Mio—First Comprehensive Exploration of Mercury’s Space Environment: Mission Overview

Author

Murakami, Go, Hayakawa, Hajime, Ogawa, Hiroyuki, Matsuda, Shoya, Seki, Taeko, Kasaba, Yasumasa, Saito, Yoshifumi, Yoshikawa, Ichiro, Kobayashi, Masanori, Baumjohann, Wolfgang, Matsuoka, Ayako, Kojima, Hirotsugu, Yagitani, Satoshi, Moncuquet, Michel, Wahlund, Jan-Erik, Delcourt, Dominique, Hirahara, Masafumi, Barabash, Stas, Korablev, Oleg, and Fujimoto, Masaki

Published

2020

3. 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

Published

2020

4. 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, Saito, Yoshifumi, Delcourt, Dominique, Hirahara, Masafumi, Barabash, Stas, Andre, Nicolas, Kobayashi, Masanori, Yoshikawa, Ichiro, Murakami, Go, and Hayakawa, Hajime

Published

2020

5. Direct Observation of L‐X Mode of Auroral Kilometric Radiation in the Lower Latitude Magnetosphere by the Arase Satellite.

Author

Zhang, Sai, Yin, Qinpei, Yang, Hongming, Xiao, Fuliang, Zhou, Qinghua, Yang, Qiwu, Tang, Jiawen, Deng, Zhoukun, Kasahara, Yoshiya, Miyoshi, Yoshizumi, Kumamoto, Atsushi, Nakamura, Yosuke, Tsuchiya, Fuminori, Shinohara, Iku, Nakamura, Satoko, Kasaba, Yasumasa, and Hori, Tomoaki

Subjects

AURORAS, MAGNETOSPHERE, LATITUDE, RAY tracing, RADIATION

Abstract

Previous studies have shown that auroral kilometric radiation (AKR) can play an important role in the magnetosphere‐atmosphere coupling and has the right‐handed extraordinary (R‐X), left‐handed ordinary (L‐O) and left‐handed extraordinary (L‐X) modes. However, the L‐X mode has not been directly observed in the lower latitude magnetosphere yet, probably because of its very limited frequency range. Here, using observations of the Arase satellite on 6 September 2018, we present an AKR event with two distinct bands (8–20 and 300–1000 kHz) around the location: L = 8 and latitude = −37°. The low (high) band is identified as the L‐X (R‐X) mode based on the polarization and frequency ranges. Simulations of 3‐D ray tracing show that most of ray paths with 14 (11 and 18) kHz pass (miss) the location of Arase, basically consistent with observations. Our study provides direct evidence that the L‐X mode can propagate from high latitudes downward to lower latitudes. Plain Language Summary: Auroral kilometric radiation (AKR) is a widely existing radio emission with kilometric wavelength at the Earth, contributing to the magnetosphere‐atmosphere coupling. Similar emissions have been observed on all magnetic planets of the solar system. Previous studies have shown that AKR primarily occurs in the R‐X mode, with a small contribution in the L‐O and L‐X modes. The L‐X mode at lower latitudes has not been directly observed so far, most likely due to its extremely limited frequency range. Here, we present an L‐X mode (peak frequency ∼14 kHz) in the lower latitude magnetosphere observed by the Arase satellite. Using the 3‐D ray tracing method, we simulate ray paths with different initial wave parameters and source locations. Simulations show that ray paths with 14 (11 and 18) kHz pass (miss) the location of the Arase satellite and are highly dependent on initial wave parameters and the location of source. Our results provide a direct evidence that the L‐X mode from high latitude source regions can propagate downward to lower latitudes under suitable conditions. This study enriches the understanding of AKR propagation characteristics in the magnetosphere. Key Points: An auroral kilometric radiation (AKR) event with two distinct bands (8–20 kHz and 300–1000 kHz) is observed around the location: L = 8 and latitude = −37°Based on the polarization and frequency ranges, the low (high) band AKR is identified as the L‐X (R‐X) mode3‐D ray tracing simulations show that L‐X mode can propagate downward to lower latitudes, basically consistent with observations [ABSTRACT FROM AUTHOR]

Published

2024

6. Simulation of Dawn‐To‐Dusk Electric Field in the Jovian Inner Magnetosphere via Region 2‐Like Field‐Aligned Current.

Author

Nakamura, Yuki, Terada, Koichiro, Tao, Chihiro, Terada, Naoki, Kasaba, Yasumasa, Leblanc, François, Kita, Hajime, Nakamizo, Aoi, Yoshikawa, Akimasa, Ohtani, Shinichi, Tsuchiya, Fuminori, Kagitani, Masato, Sakanoi, Takeshi, Murakami, Go, Yoshioka, Kazuo, Kimura, Tomoki, Yamazaki, Atsushi, and Yoshikawa, Ichiro

Subjects

MAGNETOSPHERE, ELECTRIC potential, DYNAMIC pressure, WIND pressure, SOLAR wind, ELECTRIC fields

Abstract

The presence of the dawn‐to‐dusk electric field of about 4 mV/m in the Jovian inner magnetosphere and its response to the enhancement of the solar wind dynamic pressure are still a mystery of the rotation‐dominated Jovian magnetosphere. Previous studies have suggested that magnetosphere‐ionosphere (M‐I) coupling via Region 2‐like (R2‐like) field‐aligned current (FAC) could be the origin of the Jovian dawn‐to‐dusk electric field. This study investigates whether the dawn‐to‐dusk electric field is formed from this scenario by using a Jovian ionosphere model and a two‐dimensional ionospheric potential solver. Our results show that the dawn‐dusk asymmetry in the ionospheric potential form even at middle latitudes and that the dawn‐to‐dusk electric field is induced in the inner magnetosphere if the electric potential is mapped to the magnetospheric equatorial plane. Around the Io orbit, the calculated electric field strength for the ionosphere without meteoroid influx is too large, 200 mV/m at dawn and 88 mV/m at dusk. One of the solutions is to consider long‐lived meteoric ions in the Jovian ionosphere, which reduce the electric field strength to 15 mV/m at dawn and 12 mV/m at dusk. The model also shows that the electric field strength increases with the intensity of R2‐like FAC, consistent with its response to the solar wind dynamic pressure observed by the Hisaki satellite. Key Points: The dawn‐to‐dusk electric field in the Jovian inner magnetosphere via Region 2‐like field‐aligned current was simulatedEnhancement of ionospheric conductance by meteoric ions weakens the dawn‐to‐dusk electric fieldThe simulated dawn‐to‐dusk electric field for the case including meteoroid influx can explain Hisaki observations [ABSTRACT FROM AUTHOR]

Published

2023

7. BepiColombo - Mission Overview and Science Goals

Author

Benkhoff, Johannes, Murakami, Go, Baumjohann, W., Besse, S., Bunce, E.J., Casale, Mauro, Cremonese, G., Glassmeier, K. H., Hayakawa, H., Heyner, Daniel, Hiesinger, H., Huovelin, Juhani, Hussmann, H., Iafolla, V., Iess, Luciano, Kasaba, Yasumasa, Kobayashi, Masanori, Milillo, Anna, Mitrofanov, Igor G., Montagnon, Elsa, Novara, M., Orsini, Stefano, Quemerais, Eric, Reininghaus, U., Saito, Yoshifumi, Santoli, Francesco, Stramaccioni, D., Sutherland, O., Thomas, N., Yoshikawa, I., Zender, Joe, Department of Physics, European Space Research and Technology Centre (ESTEC), European Space Agency (ESA), Japan Aerospace Exploration Agency [Sagamihara] (JAXA), Space Research Institute of Austrian Academy of Sciences (IWF), Austrian Academy of Sciences (OeAW), European Space Astronomy Centre (ESAC), School of Physics and Astronomy [Leicester], University of Leicester, INAF - Osservatorio Astronomico di Padova (OAPD), Istituto Nazionale di Astrofisica (INAF), Institut für Geophysik und Extraterrestrische Physik [Braunschweig] (IGEP), Technische Universität Braunschweig = Technical University of Braunschweig [Braunschweig], Institute of Space and Astronautical Science (ISAS), Institut für Planetologie [Münster], Westfälische Wilhelms-Universität Münster (WWU), Department of Physics [Helsinki], Falculty of Science [Helsinki], University of Helsinki-University of Helsinki, DLR Institut für Planetenforschung, Deutsches Zentrum für Luft- und Raumfahrt [Berlin] (DLR), Istituto di Astrofisica e Planetologia Spaziali - INAF (IAPS), Dipartimento di Ingegneria Meccanica e Aerospaziale [Roma La Sapienza] (DIMA), Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome], Planetary Plasma and Atmospheric Research Center [Sendai] (PPARC), Tohoku University [Sendai], Planetary Exploration Research Center [Chiba] (PERC), Chiba Institute of Technology (CIT), Space Research Institute of the Russian Academy of Sciences (IKI), Russian Academy of Sciences [Moscow] (RAS), European Space Operations Center (ESOC), HELIOS - LATMOS, Laboratoire Atmosphères, Milieux, Observations Spatiales (LATMOS), Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS), Physikalisches Institut [Bern], Universität Bern [Bern], Department of Complexity Science and Engineering [Tokyo], and The University of Tokyo (UTokyo)

Subjects

SURFACE, 010504 meteorology & atmospheric sciences, BepiColombo, Scientific Space Mission, Missions, 114 Physical sciences, 01 natural sciences, MAGNETOSPHERE, Planetary and Magnetospheric Science, 0103 physical sciences, MESSENGER OBSERVATIONS, SPECTROMETER, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, MERCURY ORBITER MISSION, Mercury exploration, 520 Astronomy, Science Goals, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy and Astrophysics, Mercury, 620 Engineering, CORNERSTONE MISSION, Surface and Interior, GAMMA-RAY, [SDU]Sciences of the Universe [physics], POLAR DEPOSITS, Space and Planetary Science, Fundamental Physics, Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics, VENUS, GENERATION

Abstract

BepiColombo is a joint mission between the European Space Agency, ESA, and the Japanese Aerospace Exploration Agency, JAXA, to perform a comprehensive exploration of Mercury. Launched on $20^{\mathrm{th}}$ 20 th October 2018 from the European spaceport in Kourou, French Guiana, the spacecraft is now en route to Mercury.Two orbiters have been sent to Mercury and will be put into dedicated, polar orbits around the planet to study the planet and its environment. One orbiter, Mio, is provided by JAXA, and one orbiter, MPO, is provided by ESA. The scientific payload of both spacecraft will provide detailed information necessary to understand the origin and evolution of the planet itself and its surrounding environment. Mercury is the planet closest to the Sun, the only terrestrial planet besides Earth with a self-sustained magnetic field, and the smallest planet in our Solar System. It is a key planet for understanding the evolutionary history of our Solar System and therefore also for the question of how the Earth and our Planetary System were formed.The scientific objectives focus on a global characterization of Mercury through the investigation of its interior, surface, exosphere, and magnetosphere. In addition, instrumentation onboard BepiColombo will be used to test Einstein’s theory of general relativity. Major effort was put into optimizing the scientific return of the mission by defining a payload such that individual measurements can be interrelated and complement each other.

Published

2021

8. 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

9. 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

10. Variation of Jupiter's Aurora Observed by Hisaki/EXCEED: 4. Quasi‐Periodic Variation.

Author

Tao, Chihiro, Kimura, Tomoki, Kronberg, Elena A., Tsuchiya, Fuminori, Murakami, Go, Yamazaki, Atsushi, Vogt, Marissa F., Bonfond, Bertrand, Yoshioka, Kazuo, Yoshikawa, Ichiro, Kasaba, Yasumasa, Kita, Hajime, and Okamoto, Shogo

Abstract

Quasi‐periodic variations of a few to several days are observed in the energetic plasma and magnetic dipolarization in Jupiter's magnetosphere. Variation in the plasma mass flux related to Io's volcanic activity is proposed as a candidate for the variety of the period. Using a long‐term monitoring of Jupiter's northern aurora by the Earth‐orbiting planetary space telescope Hisaki, we analyzed the quasi‐periodic variation seen in the auroral power integrated over the northern pole for 2014–2016, which included monitoring Io's volcanically active period in 2015 and the solar wind near Jupiter during Juno's approach phase in 2016. Quasi‐periodic variation with periods of 0.8–8 days was detected. The difference between the periodicities during volcanically active and quiet periods is not significant. Our data set suggests that the difference of period between volcanically active and quiet conditions is below 1.25 days. This is consistent with the expected difference estimated from a proposed relationship based on a theoretical model applied to the plasma variation of this volcanic event. The periodicity does not show a clear correlation with the auroral power, central meridional longitude, nor Io phase angle. The periodic variation is continuously observed in addition to the auroral modulation due to solar wind variation. Furthermore, Hisaki auroral data sometimes shows particularly intense auroral bursts of emissions lasting <10 h. We find that these bursts coincide with peaks of the periodic variations. Moreover, the occurrence of these bursts increases during the volcanically active period. This auroral observation links parts of previous observations to give a global view of Jupiter's magnetospheric dynamics.Key Points: Quasi‐periodic variations of a few to several days seen in Jupiter's polar‐integrated northern aurora observed by HisakiAuroral bursts <10 h sometimes seen at peak of periodic variation, whose occurrence increases with Io's volcanic activityThis periodic variation additionally seen in aurora intensity enhancements associated with solar wind variations [ABSTRACT FROM AUTHOR]

Published

2021

11. ERG - A small-satellite mission to investigate the dynamics of the inner magnetosphere

Author

Watanabe, S., Inner, Magnetosphere Subgroup in the Society of Geomagnetism and Earth Planetary and Space Sciences, Shiokawa, K., Seki, K., Miyoshi, Y., Ieda, A., Ono, T., Iizima, M., Nagatsuma, T., Obara, T., Takashima, Takeshi, Asamura, Kazushi, Kasaba, Yasumasa, Matsuoka, Ayako, Saito, Yoshifumi, Saito, Hirobumi, Hirahara, M., Tonegawa, Y., Toyama, F., Tanaka, M., Nose, M., Kasahara, Y., Yumoto, K., Kawano, H., Yoshikawa, A., Ebihara, Y., Yukimatsu, A., and Sato, N.

Subjects

Physics, Atmospheric Science, Range (particle radiation), Aerospace Engineering, Magnetosphere, Astronomy, Astronomy and Astrophysics, Radiation, Space weather, Particle acceleration, symbols.namesake, Geophysics, Space and Planetary Science, Van Allen radiation belt, Physics::Space Physics, symbols, General Earth and Planetary Sciences, Particle, Satellite

Abstract

著者人数：27名, Accepted: 2005-05-15, 資料番号: SA1000450000

Published

2006

12. Relation between a photoelectron distribution observed at GEOTAIL Satellite and the electric potential of the satellite

Author

Shimoda, Tadahiro, Machida, Shinobu, Mukai, Toshifumi, Saito, Yoshifumi, Kasaba, Yasumasa, and Hayakawa, Hajime

Subjects

electron energy, 磁気圏, 電子エネルギー, GEOTAIL satellite, space plasma, Lorentz force, 光電子, ローレンツ力, satellite surface, artificial satellite, 人工衛星, GEOTAIL衛星, magnetosphere, 衛星表面, 宇宙プラズマ, photoelectron

Abstract

資料番号: AA0048468025, レポート番号: JAXA-SP-04-010

Published

2005

13. SCOPE project: Summary of the discussion on satellite systems

Author

Saito, Yoshifumi, Kasaba, Yasumasa, Maezawa, Kiyoshi, and Kojima, Hirotsugu

Subjects

general overview, magnetic field reconnection, SCOPE mission, 磁気圏, 地球磁気圏尾部, plasma environment, geomagnetic tail, GEOTAIL satellite, SCOPEミッション, プラズマ環境, 磁場リコネクション, space plasma, high spatial resolution, 総覧, GEOTAIL衛星, magnetosphere, 高位置分解能, 宇宙プラズマ

Abstract

資料番号: AA0045441039

Published

2003

14. Impulsively Excited Nightside Ultralow Frequency Waves Simultaneously Observed on and off the Magnetic Equator.

Author

Takahashi, Kazue, Denton, Richard E., Motoba, Tetsuo, Matsuoka, Ayako, Kasaba, Yasumasa, Kasahara, Yoshiya, Teramoto, Mariko, Shoji, Masafumi, Takahashi, Naoko, Miyoshi, Yoshizumi, Nosé, Masahito, Kumamoto, Atsushi, Tsuchiya, Fuminori, Redmon, Robert J., and Rodriguez, Juan V.

Subjects

MAGNETOSPHERE, SPACE vehicles, TOROIDAL harmonics, PLASMASPHERE, WAVE packets

Abstract

Abstract: The Arase spacecraft is capable of observing ultralow frequency waves in the inner magnetosphere at intermediate magnetic latitudes, a region sparsely covered by previous spacecraft missions. We report a series of impulsively excited fundamental toroidal mode standing Alfvén waves in the midnight sector observed by Arase outside the plasmasphere at magnetic latitudes 13–24°. The wave onsets are concurrent with Pi2 onsets detected by the Van Allen Probe B spacecraft at the magnetic equator in the duskside plasmasphere and by ground magnetometers at low latitudes. The duration of each toroidal wave packet is ∼20 min, which is much longer than that of the corresponding Pi2 wave packet. The toroidal waves cannot be the source of high‐latitude Pi2 waves because they were not detected on the ground near the magnetic field footprint of Arase. Overall, the toroidal wave event lasted more than 2 hr and allowed us to use the wave frequency to estimate the plasma mass density at L = 6.1–8.3. The mass density (in amu/cm3) is higher than the electron density (cm−3) by a factor of ∼6, which implies that 17–33% of the ions were O+. [ABSTRACT FROM AUTHOR]

Published

2018

15. Evaluation of the Asymmetry in Photoelectron Distribution Around the GEOTAIL Spacecraft.

Author

Shimoda, Tadahiro, Machida, Shinobu, Mukai, Toshifumi, Saito, Yoshifumi, Kasaba, Yasumasa, and Hayakawa, Hajime

Subjects

SPACE vehicles, ASTRONAUTICS, NAVIGATION (Astronautics), ROCKETRY, VEHICLES, SPACE flight, ARTIFICIAL satellites, EXPANDABLE space structures, LUNAR excursion module, MICROSPACECRAFT

Abstract

We examine photoelectron distributions detected by the low-energy-particle (LEP) instrument onboard the GEOTALL spacecraft by means of both data analysis and numerical simulations. Statistical data analysis shows asymmetries in the photoelectron distributions. For photoelectrons incident normal to the spacecraft spin axis, a higher flux is observed in the dawnward than in the duskward sector of the LEP. The distribution significantly depends on the ratio of the photoelectron energy to the spacecraft potential. Our numerical simulations reveal that the asymmetry is caused by the electrostatic potential around the thin antenna located at +18° anticlockwise (viewed from the top) relative to the LEP. Photoelectrons in the dawnward sector are preferentially carried from the sunlit surface by this potential. For upward/downward incident photoelectrons, a higher flux of upward photoelectrons is observed in the antisunward than in the sunward sector, whereas downward photoelectrons show a weak asymmetry. Our numerical simulations demonstrate that the greater flux of upward photoelectrons is caused by the electrons emitted from the sunlit surface; they are attracted to the antisunward sector. Based on these results, the asymmetries in the photoelectron distribution measured around GEOTAIL are found to be caused by the asymmetric positioning of the thin antennas relative to the LEP. [ABSTRACT FROM AUTHOR]

Published

2008

16. 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

17. 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