2024/08/22 更新

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写真a

ギルギス キロロス
ギルギス キロロス
KIROLOSSE M. GIRGIS
所属
国際宇宙惑星環境研究センター 助教
職名
助教
連絡先
メールアドレス
電話番号
0928026240

研究分野

  • 自然科学一般 / 素粒子、原子核、宇宙線、宇宙物理にする理論

  • 自然科学一般 / 宇宙惑星科学

  • フロンティア(航空・船舶) / 航空宇宙工学

  • 自然科学一般 / 宇宙惑星科学

  • フロンティア(航空・船舶) / 航空宇宙工学

学位

  • 博士(学術) ( 2020年9月   九州大学 )

  • 修士(理学) ( 2016年10月 )

経歴

  • 九州大学   国際宇宙惑星環境研究センター   特任助教   特定プロジェクト教員 助教

    2024年4月 - 現在

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    国名:日本国

  • 九州大学   国際宇宙惑星環境研究センター   学術研究員   学術研究院

    2022年5月 - 2024年3月

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    国名:日本国

  • 九州大学   院総合理工学府 地球環境理工学   学術研究員   学術研究員

    2020年10月 - 2022年3月

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    国名:日本国

  • カイロ大学   工学部 航空宇宙工学科   教務助手   ティーチングアシスタント

    2012年9月 - 2017年9月

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    国名:エジプト・アラブ共和国

学歴

  • 九州大学   地球環境理工学   宇宙物理学・宇宙工学

    2017年10月

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    国名: 日本国

  • カイロ大学   工学部 航空宇宙工学科   宇宙工学

    2012年10月

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    国名: エジプト・アラブ共和国

  • カイロ大学   工学部 航空宇宙工学科   航空宇宙工学

    2008年10月

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    国名: エジプト・アラブ共和国

研究テーマ・研究キーワード

  • 研究テーマ:Radiation Belt Simulations

    研究キーワード:Radiation Belt Simulations

    研究期間: 2018年10月 - 現在

  • 研究テーマ:South Atlantic Anomaly

    研究キーワード:South Atlantic Anomaly

    研究期間: 2017年10月 - 現在

  • 研究テーマ:Space Physics

    研究キーワード:Space Physics

    研究期間: 2012年10月 - 現在

  • 研究テーマ:Space Weather

    研究キーワード:Space Weather

    研究期間: 2012年10月 - 現在

  • 研究テーマ:Spacecraft Design

    研究キーワード:Spacecraft Design

    研究期間: 2012年10月 - 2024年

論文

  • Inner Radiation Belt Simulations During the Successive Geomagnetic Storm Event of February 2022 査読

    Girgis K.M., Hada T., Yoshikawa A., Matsukiyo S., Chian A.C.L., Echer E.

    Space Weather   22 ( 7 )   2024年7月   ISSN:1542-7390 eISSN:1542-7390

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    担当区分:筆頭著者, 責任著者   掲載種別:研究論文(学術雑誌)   出版者・発行元:Space Weather  

    Starting from 29 January 2022, a series of solar eruptions triggered a moderate geomagnetic storm on 3 February 2022, followed subsequently by another. Despite the typically minimal impact of unintense storms on space technology, 38 out of the 49 Starlink satellites underwent orbital decay, re-entering Earth's atmosphere. These satellite losses were attributed to enhanced atmospheric drag conditions. This study employs numerical simulations, utilizing our test particle simulation code, to investigate the dynamics of the inner radiation belt during the two magnetic storms. Our analysis reveals an increase in proton density and fluxes during the transition from the recovery phase of the first storm to the initial phase of the second, primarily driven by intense solar wind dynamic pressure. Additionally, we assess Single Event Upset (SEU) rates, which exhibit a 50% increase in comparison to initial quiet conditions.

    DOI: 10.1029/2023sw003789

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  • Critical analysis of the ULF power depression as a possible Tohoku earthquake precursor 査読

    Vyacheslav A Pilipenko, Valery A Martines-Bedenko, Akimasa Yoshikawa, Kirolosse M Girgis

    Earthquake Science   37 ( 5 )   406 - 413   2024年6月

  • Terrestrial and Martian space weather: A complex systems approach 招待 査読

    Chian A., Miranda R., Bertucci C., Blanco-Cano X., Borovsky J., Dasso S., Echer E., Franco A., Girgis K.M., González-Esparza J.A., Hada T., Hasegawa H., Hsieh S.Y., Kajdič P., Mazelle C., Rempel E., Rojas-Castillo D., Sánchez-Cano B., Sibeck D., Stepanova M., Valdés-Galicia J., Valdivia J.

    Journal of Atmospheric and Solar-Terrestrial Physics   259   2024年6月   ISSN:1364-6826 eISSN:1879-1824

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    掲載種別:研究論文(学術雑誌)   出版者・発行元:Journal of Atmospheric and Solar-Terrestrial Physics  

    A comparative overview of Terrestrial and Martian space weather is presented, with emphasis on applying the tools of complexity and nonlinear dynamics to study the spatiotemporal dynamics and structures of sun–Earth and sun–Mars space environment. The following topics are reviewed: (1) complex systems approach to solar atmosphere and solar wind; (2) complex systems approach to planetary bow shock and magnetosphere–ionosphere; (3) Martian space weather, bow shock, and magnetosphere–ionosphere; (4) imaging planetary magnetosphere–ionosphere.

    DOI: 10.1016/j.jastp.2024.106253

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  • Daily geomagnetic variations under variable IMF/solar conditions and their connection with underground conductivity changes in Japan 査読

    Takla E.M., Yoshikawa A., Uozumi T., Girgis K.M., Abdelkader A.

    Annals of Geophysics   67 ( 1 )   2024年5月   ISSN:1593-5213 eISSN:2037-416X

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    掲載種別:研究論文(学術雑誌)   出版者・発行元:Annals of Geophysics  

    Fluctuations in Solar Wind (SW) and Interplanetary Magnetic Field (IMF) have a relevant effect on the Geomagnetic Field (GF) measurements particularly during extreme space weather events. The current study investigates the variations of horizontal (H), vertical (Z) geomagnetic components under quiet and disturbed IMF and solar conditions as well as the effect of underground conductivity on the stationary geomagnetic measurements in Japan. Results of data analysis show that the response of the GF to IMF and solar parameters fluctuations is variable. The H and Z components were in good agreement with high visual correlation along a latitudinal profile across Japan during quiet times. On the other hand, during the disturbed times related to a Coronal Mass Ejection (CME) launched on 13 May 2005, the GF components varied with the disturbance of IMF and solar parameters. The H components showed highly correlated variations with a significant reduction along the examined profile due to the intensified ionospheric currents, while the Z components recorded in the northern part of Japan showed abnormal daily variations pattern (positive daily variations) with an enhanced amplitude which is opposite to the normal behavior of daily variations recorded in the central and southern parts of Japan (negative daily variations). The observed enhanced and abnormal daily variation of Z components in north Japan, which we consider a remarkable observation here, is possibly linked with underground conductivity anomaly in this region.

    DOI: 10.4401/ag-9021

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  • A simplified geospace model for satellite design 査読

    Girgis K.M., Sherif A.O.

    Advances in Space Research   73 ( 9 )   4700 - 4710   2024年5月   ISSN:0273-1177 eISSN:1879-1948

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    担当区分:筆頭著者, 責任著者   記述言語:英語   掲載種別:研究論文(学術雑誌)   出版者・発行元:Advances in Space Research  

    This study introduced a simplified, integrated computational model to estimate the drag coefficient and surface charging within the plasma wake of Low Earth Orbit (LEO) spacecraft influenced by various solar activities. The model constituted four core modules: a solver for the solar wind-magnetosphere interaction, a magnetosphere-ionosphere coupling for electric field mapping, an ionization model for the F-layer of the ionosphere, and an estimation model for excess satellite drag and plasma wake size. The initial module adopted a simplified 1D ideal Magnetohydrodynamic (MHD) model while incorporating magnetosphere-ionosphere interactions to derive electric field data near Earth's boundary. A simplified ionospheric model for the F-layer was implemented to compute the O+ and electron densities. Subsequently, the spacecraft drag coefficient and the plasma wake size were determined for varying solar wind speed inputs corresponding to quiet, intense, and extreme space weather conditions. In the case of extreme conditions with a solar wind speed of 1000 km/s, the results indicated that the excess satellite drag coefficient and plasma wake size increased to around ten percent.

    DOI: 10.1016/j.asr.2023.12.064

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  • A multi-disciplinary approach to investigate particle dynamics in the South Atlantic Magnetic Anomaly

    Kirolosse Girgis, Tohru Hada, Akimasa Yoshikawa, Shuichi Matsukiyo

    European Geosciences Union (EGU)   2024年3月

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    担当区分:筆頭著者, 責任著者  

    DOI: 10.5194/egusphere-egu24-1630

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  • LEO Proton Flux Modeling due to Solar Proton Injections during Geomagnetic Storms

    Kirolosse M. Girgis, Tohru Hada, Akimasa Yoshikawa, Shuichi Matsukiyo, Joseph Lemaire, Viviane Pierrard, Susan Samwel

    American Geophysical Union (AGU)   2023年12月

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    担当区分:筆頭著者, 責任著者  

    DOI: 10.22541/au.170328011.17032719/v1

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  • Geomagnetic Storm Effects on the LEO Proton Flux During Solar Energetic Particle Events 査読

    Girgis K.M., Hada T., Yoshikawa A., Matsukiyo S., Pierrard V., Samwel S.W.

    Space Weather   21 ( 12 )   2023年12月   ISSN:1542-7390 eISSN:1542-7390

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    記述言語:その他   掲載種別:研究論文(学術雑誌)   出版者・発行元:Space Weather  

    Abstract

    During a few solar energetic particle (SEP) events, solar protons were trapped within the geomagnetic field and reached the outer edge of the inner radiation belt. We reproduced this phenomenon by modeling the proton flux distribution at the Low‐Earth Orbit (LEO) for different geomagnetic conditions during solar particle events. We developed a three‐dimensional relativistic test particle simulation code to compute the 70–180 MeV solar proton Lorentz trajectories in low L‐shell range from 1 to 3. The Tsyganenko model (T01) generated the background static magnetic field with the IGRF (v12) model. We have selected three Dst index values: −7, −150, and −210 nT, to define quiet time, strong, and severe geomagnetic storms and to generate the corresponding inner magnetic field configurations. Our results showed that the simulated solar proton flux was more enhanced in the high‐latitude regions and more expanded toward the lower latitude range as long as the geomagnetic storm was intensified. Satellite observations and geomagnetic cutoff rigidities confirmed the numerical results. Furthermore, the LEO proton flux distribution was deformed, so the structure of the proton flux inside the South Atlantic Anomaly (SAA) became longitudinally extended as the Dst index decreased. Moreover, we have assessed the corresponding radiation environment of the LEO mission. We realized that, for a higher inclined LEO mission during an intense geomagnetic storm (Dst = −210 nT), the probability of the occurrence of the Single Event Upset (SEU) rates increased by 19% and the estimated accumulated absorbed radiation doses increased by 17% in comparison with quiet conditions.

    DOI: 10.1029/2023sw003664

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  • Radiation Analysis of LEO Mission in the South Atlantic Anomaly During Geomagnetic Storm 招待 査読

    Girgis K.M., Hada T., Matsukiyo S., Yoshikawa A.

    IEEE Journal of Radio Frequency Identification   6   292 - 298   2022年4月   eISSN:2469-7281

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    記述言語:その他   掲載種別:研究論文(学術雑誌)   出版者・発行元:IEEE Journal of Radio Frequency Identification  

    We have studied the radiation environment of LEO spacecraft when passing through the South Atlantic Anomaly (SAA) during the geomagnetic storm event of 15 May 2005. The 70-180 MeV proton flux information were numerically obtained from a simulation model of the inner radiation belt. The radiation analysis was consisted of two parts: the estimation of the Single Event Upset (SEU) rates and the absorbed radiation doses. One of the characteristics of the SAA at 800 km altitude during the recovery phase of the geomagnetic storm was the enhancement of its southern proton flux cell. It was found that the excess SEU rates and absorbed radiation doses could reach at least 200 % and 70 % respectively during the recovery phase in comparison to the initial phase of the geomagnetic storm. The estimated radiation results were in a good agreement with observations.

    DOI: 10.1109/JRFID.2022.3163441

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  • Seasonal variation and geomagnetic storm index effects on the proton flux response in the South Atlantic Anomaly by test particle simulations 査読

    Girgis K.M., Hada T., Matsukiyo S.

    Journal of Atmospheric and Solar-Terrestrial Physics   228   105808 - 105808   2022年2月   ISSN:1364-6826 eISSN:1879-1824

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    記述言語:その他   掲載種別:研究論文(学術雑誌)   出版者・発行元:Journal of Atmospheric and Solar-Terrestrial Physics  

    In order to estimate the proton flux variations occurring in the South Atlantic Anomaly (SAA) caused by the geodipole tilting angle and the Dst index variations, we performed three dimensional relativistic test particle simulations to calculate the trajectories of high-energy protons (70–180 MeV), where the static background magnetic field was calculated by the Tsyganenko models T01/TS05 combined with IGRF-12. As various parameters characterize the SAA proton flux, the study considered the maximum proton flux and the area of the SAA. Among many different parameters that define the space weather conditions, we considered the geodipole tilting angle and the Dst index. The numerical results showed that (1) the proton flux intensity was increased in the SAA for small geodipole tilting angles, which was confirmed by observations, and that (2) the proton flux intensity was also increased for significantly low Dst index.

    DOI: 10.1016/j.jastp.2021.105808

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  • Estimation of Single Event Upset (SEU) rates inside the SAA during the geomagnetic storm event of 15 May 2005 査読

    Girgis, KM; Hada, T; Matsukiyo, S

    2021 IEEE INTERNATIONAL CONFERENCE ON WIRELESS FOR SPACE AND EXTREME ENVIRONMENTS (WISEE)   9   27 - 30   2021年10月   ISSN:2380-7636 ISBN:978-0-7381-4451-1

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    記述言語:その他   掲載種別:研究論文(その他学術会議資料等)   出版者・発行元:2021 IEEE International Conference on Wireless for Space and Extreme Environments, WiSEE 2021  

    In this study, we assessed the Single Event Upset (SEU) rates of a LEO mission due to its passage in the South Atlantic Anomaly (SAA) during a geomagnetic storm. The South Atlantic Anomaly (SAA) represents a dangerous source of radiation for the LEO operations. Since the space weather continuously affects the inner magnetosphere condition, therefore, the inner radiation belt is subjected to significant variations, in particular during extreme space weather conditions. As the radiation environment depends essentially on the particle flux information, we have developed a numerical model to simulate the inner proton belt dynamics. In our previous work [Girgis et al. (2020b)], the short-Term variations of the inner proton belt was investigated according to the geomagnetic storm event of 15 May 2005 and the kinetic energy range for the implemented protons was from 70 to 180 MeV. The objective of this paper is to extend the previous work by assessing the corresponding SEU rates of the RAM devices mounted in a spacecraft operating in a circular orbit of 850 km, given the proton flux map information as the output results of the inner proton belt numerical model. It was concluded from the inner proton belt simulations during the geomagnetic storm, that the SAA proton flux was significantly enhanced, by > 10 % after the beginning of the storm and during the recovery storm phase. Consequently, the SEU rates were increased by 40 % during the recovery phase of the geomagnetic storm. The earlier and more accurate prediction of the SEU rates can save a LEO satellite mission from unexpected proton-induced single event upset rates during extreme space weather conditions such as geomagnetic storms.

    DOI: 10.1109/wisee50203.2021.9613828

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  • Inner radiation belt simulations of the proton flux response in the South Atlantic Anomaly during the Geomagnetic Storm of 15 May 2005 査読

    Girgis, KM; Hada, T; Matsukiyo, S; Yoshikawa, A

    JOURNAL OF SPACE WEATHER AND SPACE CLIMATE   11   48 - 48   2021年9月   ISSN:2115-7251 eISSN:2115-7251

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    記述言語:その他   掲載種別:研究論文(学術雑誌)   出版者・発行元:Journal of Space Weather and Space Climate  

    A test particle simulation code was developed to simulate the inner proton belt response during the intense geomagnetic storm of 15 May 2005. The guiding center model was implemented to compute the proton trajectories with an energy range of 70–180 MeV. The time-varying magnetic field model implemented in the simulations was computed by the Tsyganenko model TS05 with the associated inductive electric field. One of the most important features of the low-earth orbit (LEO) environment is the South Atlantic Anomaly, which imposes a dangerous radiation load on most LEO missions. This research aims to investigate the proton flux variations in the anomaly region with respect to space weather conditions. The results showed that during the main phase of the geomagnetic storm, the proton flux in the SAA decreased, whereas, throughout the initial and recovery phases, the proton flux was increased at most of the altitudes. Satellite measurements confirmed numerical results.

    添付ファイル: swsc210016.pdf

    DOI: 10.1051/swsc/2021031

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  • Solar wind parameter and seasonal variation effects on the South Atlantic Anomaly using Tsyganenko Models 査読

    Girgis, KM; Hada, T; Matsukiyo, S

    EARTH PLANETS AND SPACE   72 ( 1 )   2020年12月   ISSN:13438832 eISSN:1880-5981

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    記述言語:英語   掲載種別:研究論文(学術雑誌)   出版者・発行元:Earth, Planets and Space  

    We studied the space weather effects on the South Atlantic Anomaly (SAA) magnetic response using Tsyganenko models. For the physical parameters characterizing the SAA, the study considered the minimum magnetic field, the location (longitude and latitude) of the SAA center, and the area of the SAA. Regarding the space weather parameters, we considered the solar wind dynamic pressure, the interplanetary magnetic field components, ByIMF and BzIMF, the Dst index, and the geodipole tilting angle. To study the magnetic field response of the SAA, several different versions of the Tsyganenko models, namely, T96, T01, and TS05, were used to describe the external magnetic field contributions. The main internal magnetic field was calculated by the International Geomagnetic Reference Field (IGRF-12). The magnetic field study of the SAA was realized in long- and short-term (seasonal and diurnal) variations. We found that the Dst index and the geodipole tilting angle were the strongest influencing parameters on the SAA magnetic field response at all altitudes. Moreover, it was revealed that both magnetic poles might be a possible cause of the SAA magnetic field response, resulting from the space weather conditions. Furthermore, the magnetic field behavior of the SAA was affected by hourly variations, where the largest changes occurred at dayside.[Figure not available: see fulltext.].

    添付ファイル: 0615KG_publication1.pdf

    DOI: 10.1186/s40623-020-01221-2

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    その他リンク: http://link.springer.com/article/10.1186/s40623-020-01221-2/fulltext.html

  • Space Weather Effects on Proton Flux Variations in the South Atlantic Anomaly: A Numerical Study performed by Test Particle Simulations

    Kirolosse Girgis, Tohru Hada, Shuichi Matsukiyo

    European Geosciences Union (EGU)   2020年3月

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    記述言語:英語   掲載種別:研究論文(研究会,シンポジウム資料等)   出版者・発行元:Copernicus GmbH  

    <p>In this study, we assess the hourly variations of the three-dimensional proton flux distribution inside the South Atlantic Anomaly (SAA) during a geomagnetic storm. We have developed a relativistic three-dimensional guiding center test particle simulation code in order to compute the proton trajectories in a time-varying magnetic field background provided by Tsyganenko model TS05 and the corresponding time-varying inductive electric field. The Dst index is the main input parameter to the simulation model, while the maximum proton flux, the area of the SAA calculated below a selected threshold, and the penetration depth of the protons are the main output variables investigated in this study were. Since the LEO spacecraft and human-related activities are already affected by space weather conditions, the South Atlantic Anomaly (SAA) is also believed to create an additional source of risk. As the radiation environment depends essentially on the particle flux, the objective of this study is to estimate quantitatively the proton flux variations inside the South Atlantic Anomaly (SAA) in quiet and in storm conditions. So far, it was found that after several drift periods, the protons in the South Atlantic Anomaly (SAA) could penetrate to lower altitudes during geomagnetic storm event, and that, the SAA maximum flux value and the corresponding area, varied differently with respect to altitudes. Numerical results were compared with observations by NOAA 17 and RD3R2 instrument mounted on International Space Station (ISS).</p>

    添付ファイル: egu.pdf

    DOI: 10.5194/egusphere-egu2020-1551

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  • Long-Term Variations of the Solar Wind Effects on South Atlantic Anomaly (SAA) using Tsyganenko Model 査読

    Kirolosse M. Girgis, Tohru Hada

    Proceedings of International Exchange and Innovation Conference on Engineering & Science (IEICES)   4   2018年10月

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    記述言語:英語   掲載種別:研究論文(その他学術会議資料等)  

  • Long-Term Variations of the Solar Wind Effects on South Atlantic Anomaly (SAA) using Tsyganenko Model 査読

    Kirolosse M. Girgis, Tohru Hada

    Proceedings of International Exchange and Innovation Conference on Engineering & Science (IEICES)   4   2018年10月

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    担当区分:筆頭著者, 責任著者   記述言語:英語   掲載種別:研究論文(国際会議プロシーディングス)  

    添付ファイル: 0615KG_publication3.pdf

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▼全件表示

MISC

  • 試験粒子シミュレーションによる2022年2月磁気嵐現象が内部放射線帯に及ぼす影響

    GIRGIS Kirolosse, HADA Tohru, MATSUKIYO Shuichi, MATSUKIYO Shuichi, YOSHIKAWA Akimasa, YOSHIKAWA Akimasa, CHIAN Abraham, CHIAN Abraham

    地球電磁気・地球惑星圏学会総会及び講演会(Web)   154th   2023年

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所属学協会

  • Society of Geomagnetism and Earth, Planetary and Space Sciences (SGEPSS)

  • European Geosciences Union (EGU)

  • Japan Geoscience Union (JpGU)

学術貢献活動

  • Screening of academic papers 国際学術貢献

    役割:審査・評価, 査読

    2016年10月 - 現在

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    種別:査読等 

    外国語雑誌 査読論文数:4

    国際会議録 査読論文数:6