Approximate Calculation of the Thermal Loss of the Atmosphere of a Hot Exoplanet in a Low Orbit with Taking into Account the Ellipticity

IF 1.3 4区物理与天体物理 Q3 ASTRONOMY & ASTROPHYSICS

Astrophysical Bulletin Pub Date : 2023-07-17 DOI:10.1134/S1990341323020098

A. A. Simonova, V. I. Shematovich

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Abstract

The paper presents the results of calculations using an approximate approach to estimating the thermal loss of the atmosphere of a hot exoplanet. The objective of simulation was to study a system of a yellow dwarf of the spectral type G with an exoplanet like a hot sub-Neptune or super-Earth. Estimates of the atmospheric loss rate for a hot sub-Neptune in weakly and strongly elliptical orbits are obtained. Calculations have shown that the atmospheric loss \(\dot{M}_{T}\) averaged over the orbital period of the model hot sub-Neptune varies from \(5.8\times 10^{17}\) g for an orbit with \(e=0.0\) to \(2.6\times 10^{18}\) g for an orbit with \(e=0.8\), that is, it increases by almost 4.5 times. Moreover, for \(e=0.2,0.4,\) and \(0.6\) the values of \(\dot{M}_{T}\) are equal to \(6.3\times 10^{17}\) g, \(7.6\times 10^{17}\) g, and \(1.2\times 10^{18}\) g respectively. Using the average atmospheric mass loss per orbit, we can approximately estimate the time of total atmospheric escape of the considered sub-Neptune—at \(e=0.0\), this time is approximately equal to 0.32 billion years, and at \(e=0.8\)—approximately 0.07 billion years. Accordingly, we can conclude that the initial ellipticity of the hot exoplanet’s orbit is an important factor in estimating the loss rate of the primary hydrogen-helium atmosphere for sub-Neptunes and super-Earths.

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考虑椭圆率的低轨道热系外行星大气热损失的近似计算

本文介绍了用近似方法估计热系外行星大气热损失的计算结果。模拟的目的是研究一个光谱型为G的黄矮星系统，它有一颗像热的次海王星或超级地球这样的系外行星。得到了在弱和强椭圆轨道上热海王星下的大气损失率的估计。计算表明，在模型热亚海王星的轨道周期内，大气损失\(\dot{M}_{T}\)的平均值从\(e=0.0\)轨道的\(5.8\times 10^{17}\) g到\(e=0.8\)轨道的\(2.6\times 10^{18}\) g不等，也就是说，它增加了近4.5倍。对于\(e=0.2,0.4,\)和\(0.6\), \(\dot{M}_{T}\)的值分别等于\(6.3\times 10^{17}\) g、\(7.6\times 10^{17}\) g和\(1.2\times 10^{18}\) g。利用每轨道的平均大气质量损失，我们可以大致估算出所考虑的亚海王星的总大气逃逸时间-在\(e=0.0\)，这个时间大约等于3.2亿年，而在\(e=0.8\) -大约等于0.07亿年。因此，我们可以得出结论，热系外行星轨道的初始椭圆率是估算亚海王星和超级地球初级氢氦大气损失率的重要因素。

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

Astrophysical Bulletin 地学天文-天文与天体物理

CiteScore

2.00

自引率

33.30%

发文量

审稿时长

>12 weeks

期刊介绍： Astrophysical Bulletin is an international peer reviewed journal that publishes the results of original research in various areas of modern astronomy and astrophysics, including observational and theoretical astrophysics, physics of the Sun, radio astronomy, stellar astronomy, extragalactic astronomy, cosmology, and astronomy methods and instrumentation.