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海王星上未探测到氢的大气学意义。

Atmospheric implications of the lack of H detection at Neptune.

作者信息

Moore L, Moses J I, Melin H, Stallard T S, O'Donoghue J

机构信息

Boston University, Boston, MA, USA.

Space Science Institute, Boulder, CO, USA.

出版信息

Philos Trans A Math Phys Eng Sci. 2020 Dec 25;378(2187):20200100. doi: 10.1098/rsta.2020.0100. Epub 2020 Nov 9.

Abstract

H has been detected at all of the solar system giant planets aside from Neptune. Current observational upper limits imply that there is far less H emission at Neptune than rudimentary modelling would suggest. Here, we explore via modelling a range of atmospheric conditions in order to find some that could be consistent with observational constraints. In particular, we consider that the upper atmosphere might be much cooler than it was during the 1989 Voyager 2 encounter, and we examine the impact of an enhanced influx of external material that could act to reduce H density. Resulting ionosphere models that are consistent with existing H observational constraints have an exospheric temperature of 450 K or less, 300 K lower than the Voyager 2 value. Alternatively, if a topside CO influx of 2 × 10 cm s is imposed, the upper atmospheric temperature can be higher, up to 550 K. The potential cooling of Neptune's atmosphere is relevant for poorly understood giant planet thermospheric energetics, and would also impact aerobreaking manoeuvers for any future spacecraft. Such a large CO influx, if present, could imply Triton is a very active moon with prominent atmospheric escape, and/or that Neptune's rings significantly modify its upper atmosphere, and the introduction of so much exogenic material would complicate interpretation of the origin of species observed in Neptune's lower atmosphere. This article is part a discussion meeting issue 'Future exploration of ice giant systems'.

摘要

除海王星外,在太阳系所有气态巨行星上均已探测到氢。目前的观测上限表明,海王星上的氢排放量远低于初步模型的预测。在此,我们通过建模探索一系列大气条件,以寻找一些符合观测约束的条件。特别是,我们认为高层大气可能比1989年“旅行者2号”飞掠时要冷得多,并研究了外部物质流入增加可能对降低氢密度产生的影响。与现有氢观测约束相符的电离层模型,其外层温度为450K或更低,比“旅行者2号”测得的值低300K。或者,如果上层大气一氧化碳的流入量为2×10厘米每秒,那么高层大气温度可能会更高,最高可达550K。海王星大气可能出现的降温,对于了解甚少的气态巨行星热层能量学具有重要意义,也会影响未来任何航天器的气动制动操作。如此大量的一氧化碳流入(如果存在的话),可能意味着海卫一是一颗非常活跃的卫星,存在显著的大气逃逸现象,和/或海王星环对其高层大气有显著影响,而如此大量外源物质的引入会使对海王星低层大气中观测到的物种起源的解释变得复杂。本文是“冰巨行星系统的未来探索”讨论会议文集的一部分。

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