Revealing the Local Time Structure of the Alfvén Radius and Travel Times in Jupiter's Magnetosphere

IF 3.9 1区地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS

Journal of Geophysical Research: Planets Pub Date : 2024-10-13 DOI:10.1029/2024JE008414

A. Jenkins, L. C. Ray, T. Fell, S. V. Badman, C. T. S. Lorch

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引用次数: 0

Abstract

Jovian magnetospheric plasma is coupled to the ionosphere through Alfvén waves. Alfvén waves enable the transport of angular momentum and energy between the planet and magnetospheric plasma, a process that ultimately generates Jupiter's bright auroral emissions. However, past the Alfvén radius, the location where the radial velocity is greater than the Alfvén velocity, magnetospheric plasma is decoupled from the planet. Alfvén waves launched by magnetospheric plasma do not reach the ionosphere, angular momentum cannot be transported from the planet, and auroral emissions should diminish. Knowledge of Jupiter's Alfvén radius location is critical for interpreting drivers of auroral emissions, in situ data, and applications of numerical models. Previous studies that determined the location of the Alfvén radius assumed an azimuthally symmetric magnetosphere and local-time independent magnetic field. Here, we employ a statistical description of the magnetic field that includes local time effects. We find a minimum Alfvén radius of 30 $R_{J}$ (Jupiter radii) at 6 LT, with plasma decoupled from the planet in the post-dusk through dawn sector. Furthermore, no Alfvén radius exists within 60 $R_{J}$ between 8 and 20 LT. At distances greater than 50 $R_{J}$ , the Alfvén travel time is such that magnetospheric plasma moves substantially in the magnetosphere before angular momentum can be efficiently transferred from the atmosphere. Therefore, the angular momentum supplied may no longer be sufficient for the local conditions. Our results highlight the importance of local time considerations and offer new interpretations for local time dependent auroral features, such as the polar collar.

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揭示木星磁层中阿尔芬半径和旅行时间的本地时间结构

木星磁层等离子体通过阿尔弗文波与电离层耦合。阿尔芬波使角动量和能量在行星和磁层等离子体之间传输，这一过程最终产生了木星明亮的极光辐射。然而，过了阿尔弗文半径（即径向速度大于阿尔弗文速度的位置），磁层等离子体就与行星脱钩了。磁层等离子体发射的阿尔弗文波无法到达电离层，角动量也无法从行星上传播，极光辐射应该会减弱。了解木星阿尔芬半径的位置对于解释极光辐射的驱动因素、现场数据和数值模型的应用至关重要。以前确定阿尔弗文半径位置的研究假定磁层是方位对称的，磁场与当地时间无关。在这里，我们采用了包含局部时间效应的磁场统计描述。我们发现在 6 LT 时，等离子体与行星在黄昏后到黎明前的扇形区域脱钩，最小阿尔弗文半径为 30 R J ${\mathrm{R}}_{J}$（木星半径）。此外，在 8 至 20 LT 期间，60 R J ${\mathrm{R}}_{J}$ 范围内不存在阿弗文半径。在距离大于 50 R J ${\mathrm{R}}_{J}$ 时，阿尔弗文移动时间使得磁层等离子体在磁层中大幅移动，然后角动量才能从大气中有效转移。因此，提供的角动量可能不再足以满足当地条件。我们的结果突出了当地时间因素的重要性，并为极圈等与当地时间有关的极光特征提供了新的解释。

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来源期刊

Journal of Geophysical Research: Planets Earth and Planetary Sciences-Earth and Planetary Sciences (miscellaneous)

CiteScore

8.00

自引率

27.10%

发文量

254

期刊介绍： The Journal of Geophysical Research Planets is dedicated to the publication of new and original research in the broad field of planetary science. Manuscripts concerning planetary geology, geophysics, geochemistry, atmospheres, and dynamics are appropriate for the journal when they increase knowledge about the processes that affect Solar System objects. Manuscripts concerning other planetary systems, exoplanets or Earth are welcome when presented in a comparative planetology perspective. Studies in the field of astrobiology will be considered when they have immediate consequences for the interpretation of planetary data. JGR: Planets does not publish manuscripts that deal with future missions and instrumentation, nor those that are primarily of an engineering interest. Instrument, calibration or data processing papers may be appropriate for the journal, but only when accompanied by scientific analysis and interpretation that increases understanding of the studied object. A manuscript that describes a new method or technique would be acceptable for JGR: Planets if it contained new and relevant scientific results obtained using the method. Review articles are generally not appropriate for JGR: Planets, but they may be considered if they form an integral part of a special issue.