Effects of the evolving early Moon and Earth magnetospheres

IF 2.6 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS
James Green, Scott Boardsen, Chuanfei Dong
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Abstract

Recently it has been identified that our Moon had an extensive magnetosphere for several hundred million years soon after it was formed when the Moon was within 20 Earth Radii (R E ) from the Earth. Some aspects of the interaction between the early Earth-Moon magnetospheres are investigated by mapping the interconnected field lines between the Earth and the Moon and investigating how the early lunar magnetosphere affects the magnetospheric dynamics within the coupled magnetospheres over time. So long as the magnetosphere of the Moon remains strong as it moves away from the Earth in the antialigned dipole configuration, the extent of the Earth’s open field lines decreases. As a result, at times it significantly changes the structure of the field-aligned current system, pushing the polar cusp significantly northward, and forcing magnetotail reconnection sites into the deeper tail region. In addition, the combined magnetospheres of the Earth and the Moon greatly extend the number of closed field lines enabling a much larger plasmasphere to exist and connecting the lunar polar cap with closed field lines to the Earth. That configuration supports the transfer of plasma between the Earth and the Moon potentially creating a time capsule of the evolution of volatiles with depth. This paper only touches on the evolution of the early Earth and Moon magnetospheres, which has been a largely neglected space physics problem and has great potential for complex follow-on studies using more advanced tools and due to the expected new lunar data coming in the next decade through the Artemis Program.
早期月球和地球磁层演化的影响
最近已经确定,我们的月球在形成后不久的几亿年内有一个广泛的磁层,当时月球距离地球不到20个地球半径(R E)。通过绘制地球和月球之间相互连接的磁场线,并研究早期月球磁层如何随时间影响耦合磁层内的磁层动力学,研究了早期地月磁层之间相互作用的某些方面。只要月球的磁层在它以反对准的偶极子结构远离地球时保持强大,地球的开放磁力线的范围就会减小。因此,有时它显著地改变了场向电流系统的结构,将极尖显著地向北推,并迫使磁尾重联点进入更深的尾区。此外,地球和月球的磁层的结合大大延长了封闭磁力线的数量,使更大的等离子层存在,并将具有封闭磁力线的月球极帽连接到地球。这种结构支持等离子体在地球和月球之间的转移,可能会创造一个时间胶囊,记录挥发物随深度的演变。本文仅涉及早期地球和月球磁层的演变,这在很大程度上是一个被忽视的空间物理问题,并且由于通过阿尔忒弥斯计划预计在未来十年将获得新的月球数据,因此使用更先进的工具进行复杂的后续研究具有很大的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Frontiers in Astronomy and Space Sciences
Frontiers in Astronomy and Space Sciences ASTRONOMY & ASTROPHYSICS-
CiteScore
3.40
自引率
13.30%
发文量
363
审稿时长
14 weeks
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