火星的外大气层可以通过高光谱分辨率望远镜进行跟踪,例如线发射成像仪

J. Carter, K. Dennerl, K. Kuntz, W. Dunn, D. Bodewits, C. Jackman, S. Sembay, G. Branduardi-Raymont, T. Deskins, D. Koutroumpa, R. Kraft, C. Lisse, S. McEntee, S. Wolk, F. S. Porter
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引用次数: 1

摘要

火星为我们提供了当地未磁化陆地行星的类似物,因此是了解系外行星可居住性的关键。全球磁场的缺乏意味着大气层会直接与太阳风相互作用,导致大气层的大量损失。虽然现场测量提供了大量详细的局部信息,但在推导全球情况方面却很有限。相比之下,远程 X 射线观测可以在多个季节提供重要的全球瞬时覆盖范围,并对不同的太阳风进行采样。先前的 XMM-牛顿观测通过太阳风电荷交换发射(SWCX)机制从扩展的行星晕和大气荧光中探测到了大量通量。相比之下,钱德拉观测仅探测到一个低亮度的圆盘和一个微弱的光晕。据推测,这些观测差异是由于重离子分数增加的瞬态太阳风造成的。在此,我们展示了拟议中的 NASA 任务 "线发射成像仪 "在静态和瞬态太阳风条件下对光晕和盘区的模拟光谱。我们的研究表明,即使在中等太阳风条件下,SWCX 和荧光发射线也很容易在背景之上被探测到,从而为行星大气的损耗和特征不太明显的大气丰度的分子组成提供了新的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The exosphere of Mars can be tracked by a high-spectral resolution telescope, such as the Line Emission Mapper
Mars provides our local analogue for unmagnetized terrestrial planets and is thus key to understanding the habitability of exoplanets. The lack of a global magnetic field means that the atmosphere interacts directly with the solar wind, causing significant loss of the atmosphere. While in situ measurements provide a wealth of detailed local information, they are limited in deriving the global picture. In contrast, remote X-ray observations can provide important global instantaneous coverage over multiple seasons and sampling different solar wind. Previous XMM-Newton observations have detected significant flux via the solar wind charge exchange emission (SWCX) mechanism from an extended planetary halo, and from atmospheric fluorescence. In contrast, Chandra observations only detected a low-luminosity disk and a faint halo. It is postulated that these observational differences are due to transient solar wind with increased heavy ion fractions. Here, we present simulated spectra for the proposed NASA mission Line Emission Mapper, of both halo and disk regions, under quiet and transient solar wind. We show that even under moderate solar wind conditions, both SWCX and fluorescence emission lines are readily detected above the background, providing new insights into the loss of planetary atmospheres and the molecular composition of less well-characterised atmospheric abundances.
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