Heating, Excitation, Dissociation, and Ionization of Molecules by High-Energy Photons in Planetary Atmospheres

IF 2.9 3区 化学 Q2 CHEMISTRY, MULTIDISCIPLINARY
Antonio García Muñoz*,  and , Ewan Bataille, 
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Abstract

Photoionization by high-energy photons creates nonthermal electrons with a broad range of energies that heat and chemically transform the atmospheres of planets. The specifics of the interactions are notably different when the gas is atomic or molecular. Motivated by the idea that molecules survive to high altitudes in some exoplanets, we built a model for the energy transfer from nonthermal electrons to the H2O, H2, and O2 molecules. Our calculations show that the primary electrons of energy above about a hundred eV, a likely outcome from X-ray photoionization at moderately high atmospheric densities, expend most of their energy in ionization, dissociation, and electronic excitation collisions. In contrast, the primary electrons of less than about ten eV, such as those produced by extreme-ultraviolet photons at low densities, expend most of their energy in momentum transfer (heating), rotational, and vibrational excitation collisions. The partitioning between channels with weak thresholds is particularly sensitive to local fractional ionization. The transition between these two situations introduces a parallel transition in the way that the stellar energy is deposited in the atmosphere. Our calculations show that the nonthermal electrons enhance the ionization rate by a factor of a few or more with respect to photoionization alone but may not greatly contribute to the direct dissociation of molecules unless the local flux of far-ultraviolet photons is relatively weak. These findings highlight the importance of tracking the energy from the incident photons to the nonthermal electrons and onto the gas for problems concerned with the remote sensing and energy balance of exoplanet atmospheres.

Abstract Image

高能光子的光离子化产生了能量范围很广的非热电子,对行星大气层进行加热和化学变化。当气体是原子气体或分子气体时,相互作用的具体细节明显不同。在某些系外行星中,分子可以存活到很高的高度,受这种想法的激励,我们建立了一个从非热电子到 H2O、H2 和 O2 分子的能量转移模型。我们的计算显示,能量高于约一百电子伏特的初级电子(这可能是在中等高密度大气中发生的X射线光离子化的结果)在电离、解离和电子激发碰撞中消耗了大部分能量。相比之下,小于约 10 eV 的初级电子,如在低密度下由极紫外光子产生的电子,其大部分能量消耗在动量传递(加热)、旋转和振动激发碰撞中。弱阈值通道之间的划分对局部分数电离特别敏感。这两种情况之间的转换会导致恒星能量在大气中沉积方式的平行转换。我们的计算表明,与光离子化相比,非热电子会将电离率提高几倍或更多,但除非当地的远紫外光子通量相对较弱,否则非热电子可能不会对分子的直接解离做出很大贡献。这些发现凸显了跟踪从入射光子到非热电子再到气体的能量对于系外行星大气遥感和能量平衡问题的重要性。
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来源期刊
ACS Earth and Space Chemistry
ACS Earth and Space Chemistry Earth and Planetary Sciences-Geochemistry and Petrology
CiteScore
5.30
自引率
11.80%
发文量
249
期刊介绍: The scope of ACS Earth and Space Chemistry includes the application of analytical, experimental and theoretical chemistry to investigate research questions relevant to the Earth and Space. The journal encompasses the highly interdisciplinary nature of research in this area, while emphasizing chemistry and chemical research tools as the unifying theme. The journal publishes broadly in the domains of high- and low-temperature geochemistry, atmospheric chemistry, marine chemistry, planetary chemistry, astrochemistry, and analytical geochemistry. ACS Earth and Space Chemistry publishes Articles, Letters, Reviews, and Features to provide flexible formats to readily communicate all aspects of research in these fields.
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