Evidence for lunar tide effects in Earth’s plasmasphere

Tides are universal and affect spatially distributed systems, ranging from planetary to galactic scales. In the Earth–Moon system, effects caused by lunar tides were reported in the Earth’s crust, oceans, neutral gas-dominated atmosphere (including the ionosphere) and near-ground geomagnetic field....

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Veröffentlicht in:	Nature physics 2023-04, Vol.19 (4), p.486-491
Hauptverfasser:	Xiao, Chao, He, Fei, Shi, Quanqi, Liu, Wenlong, Tian, Anmin, Guo, Ruilong, Yue, Chao, Zhou, Xuzhi, Wei, Yong, Rae, I. Jonathan, Degeling, Alexander W., Angelopoulos, Vassilis, Masongsong, Emmanuel V., Liu, Ji, Zong, Qiugang, Fu, Suiyan, Pu, Zuyin, Zhang, Xiaoxin, Wang, Tieyan, Wang, Huizi, Zhang, Zhao
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Schlagworte:	639/33/445 639/766/1960 639/766/525 Atmosphere Atomic Classical and Continuum Physics Cold Cold plasmas Complex Systems Computer networks Condensed Matter Physics Diurnal variations Earth Earth crust Electromagnetic forces Geomagnetic field Geomagnetism Geophysics Influence Ionosphere Laboratories Letter Lunar tides Magnetospheres Mathematical and Computational Physics Molecular Moon Neutral gases Oceans Optical and Plasma Physics Physics Physics and Astronomy Plasma Plasmasphere Theoretical Tidal effects Tides
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creator	Xiao, Chao He, Fei Shi, Quanqi Liu, Wenlong Tian, Anmin Guo, Ruilong Yue, Chao Zhou, Xuzhi Wei, Yong Rae, I. Jonathan Degeling, Alexander W. Angelopoulos, Vassilis Masongsong, Emmanuel V. Liu, Ji Zong, Qiugang Fu, Suiyan Pu, Zuyin Zhang, Xiaoxin Wang, Tieyan Wang, Huizi Zhang, Zhao
description	Tides are universal and affect spatially distributed systems, ranging from planetary to galactic scales. In the Earth–Moon system, effects caused by lunar tides were reported in the Earth’s crust, oceans, neutral gas-dominated atmosphere (including the ionosphere) and near-ground geomagnetic field. However, whether a lunar tide effect exists in the plasma-dominated regions has not been explored yet. Here we show evidence of a lunar tide-induced signal in the plasmasphere, the inner region of the magnetosphere, which is filled with cold plasma. We obtain these results by analysing variations in the plasmasphere’s boundary location over the past four decades from multisatellite observations. The signal possesses distinct diurnal (and monthly) periodicities, which are different from the semidiurnal (and semimonthly) variations dominant in the previously observed lunar tide effects in other regions. These results demonstrate the importance of lunar tidal effects in plasma-dominated regions, influencing understanding of the coupling between the Moon, atmosphere and magnetosphere system through gravity and electromagnetic forces. Furthermore, these findings may have implications for tidal interactions in other two-body celestial systems. Lunar tides affect Earth’s oceans and its geomagnetic field. Multisatellite observations demonstrate that they also impact the plasmasphere.
doi_str_mv	10.1038/s41567-022-01882-8
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Jonathan ; Degeling, Alexander W. ; Angelopoulos, Vassilis ; Masongsong, Emmanuel V. ; Liu, Ji ; Zong, Qiugang ; Fu, Suiyan ; Pu, Zuyin ; Zhang, Xiaoxin ; Wang, Tieyan ; Wang, Huizi ; Zhang, Zhao</creator><creatorcontrib>Xiao, Chao ; He, Fei ; Shi, Quanqi ; Liu, Wenlong ; Tian, Anmin ; Guo, Ruilong ; Yue, Chao ; Zhou, Xuzhi ; Wei, Yong ; Rae, I. Jonathan ; Degeling, Alexander W. ; Angelopoulos, Vassilis ; Masongsong, Emmanuel V. ; Liu, Ji ; Zong, Qiugang ; Fu, Suiyan ; Pu, Zuyin ; Zhang, Xiaoxin ; Wang, Tieyan ; Wang, Huizi ; Zhang, Zhao</creatorcontrib><description>Tides are universal and affect spatially distributed systems, ranging from planetary to galactic scales. In the Earth–Moon system, effects caused by lunar tides were reported in the Earth’s crust, oceans, neutral gas-dominated atmosphere (including the ionosphere) and near-ground geomagnetic field. However, whether a lunar tide effect exists in the plasma-dominated regions has not been explored yet. Here we show evidence of a lunar tide-induced signal in the plasmasphere, the inner region of the magnetosphere, which is filled with cold plasma. We obtain these results by analysing variations in the plasmasphere’s boundary location over the past four decades from multisatellite observations. The signal possesses distinct diurnal (and monthly) periodicities, which are different from the semidiurnal (and semimonthly) variations dominant in the previously observed lunar tide effects in other regions. These results demonstrate the importance of lunar tidal effects in plasma-dominated regions, influencing understanding of the coupling between the Moon, atmosphere and magnetosphere system through gravity and electromagnetic forces. Furthermore, these findings may have implications for tidal interactions in other two-body celestial systems. Lunar tides affect Earth’s oceans and its geomagnetic field. 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However, whether a lunar tide effect exists in the plasma-dominated regions has not been explored yet. Here we show evidence of a lunar tide-induced signal in the plasmasphere, the inner region of the magnetosphere, which is filled with cold plasma. We obtain these results by analysing variations in the plasmasphere’s boundary location over the past four decades from multisatellite observations. The signal possesses distinct diurnal (and monthly) periodicities, which are different from the semidiurnal (and semimonthly) variations dominant in the previously observed lunar tide effects in other regions. These results demonstrate the importance of lunar tidal effects in plasma-dominated regions, influencing understanding of the coupling between the Moon, atmosphere and magnetosphere system through gravity and electromagnetic forces. Furthermore, these findings may have implications for tidal interactions in other two-body celestial systems. Lunar tides affect Earth’s oceans and its geomagnetic field. 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Jonathan</au><au>Degeling, Alexander W.</au><au>Angelopoulos, Vassilis</au><au>Masongsong, Emmanuel V.</au><au>Liu, Ji</au><au>Zong, Qiugang</au><au>Fu, Suiyan</au><au>Pu, Zuyin</au><au>Zhang, Xiaoxin</au><au>Wang, Tieyan</au><au>Wang, Huizi</au><au>Zhang, Zhao</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Evidence for lunar tide effects in Earth’s plasmasphere</atitle><jtitle>Nature physics</jtitle><stitle>Nat. Phys</stitle><date>2023-04-01</date><risdate>2023</risdate><volume>19</volume><issue>4</issue><spage>486</spage><epage>491</epage><pages>486-491</pages><issn>1745-2473</issn><eissn>1745-2481</eissn><abstract>Tides are universal and affect spatially distributed systems, ranging from planetary to galactic scales. In the Earth–Moon system, effects caused by lunar tides were reported in the Earth’s crust, oceans, neutral gas-dominated atmosphere (including the ionosphere) and near-ground geomagnetic field. However, whether a lunar tide effect exists in the plasma-dominated regions has not been explored yet. Here we show evidence of a lunar tide-induced signal in the plasmasphere, the inner region of the magnetosphere, which is filled with cold plasma. We obtain these results by analysing variations in the plasmasphere’s boundary location over the past four decades from multisatellite observations. The signal possesses distinct diurnal (and monthly) periodicities, which are different from the semidiurnal (and semimonthly) variations dominant in the previously observed lunar tide effects in other regions. These results demonstrate the importance of lunar tidal effects in plasma-dominated regions, influencing understanding of the coupling between the Moon, atmosphere and magnetosphere system through gravity and electromagnetic forces. Furthermore, these findings may have implications for tidal interactions in other two-body celestial systems. 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subjects	639/33/445 639/766/1960 639/766/525 Atmosphere Atomic Classical and Continuum Physics Cold Cold plasmas Complex Systems Computer networks Condensed Matter Physics Diurnal variations Earth Earth crust Electromagnetic forces Geomagnetic field Geomagnetism Geophysics Influence Ionosphere Laboratories Letter Lunar tides Magnetospheres Mathematical and Computational Physics Molecular Moon Neutral gases Oceans Optical and Plasma Physics Physics Physics and Astronomy Plasma Plasmasphere Theoretical Tidal effects Tides
title	Evidence for lunar tide effects in Earth’s plasmasphere
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