Neutral Heating Efficiency in the Dayside Martian Upper Atmosphere

Cui, Jun; Niu, Dandan; Cao, Y.; Wu, Xiaoshu; Li, J.; Wu, Zhaopeng; He, Fei; Wei, Yong

doi:10.3847/1538-3881/ab5fcc

Cited by 21 publications

(24 citation statements)

References 135 publications

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“…Sakai et al., 2015), making important contributions to local ionization (e.g. Cui et al., 2018) and heating (Gu et al., 2020). Interestingly, photoelectrons have also been observed on the nightside, where photoionization is switched off (e.g.…”

Section: Discussionmentioning

confidence: 99%

A Survey of Photoelectrons on the Nightside of Mars

Cao

Cui

et al. 2021

Geophysical Research Letters

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Photoelectrons, which are produced by solar Extreme Ultraviolet (EUV) and X-ray ionization of various neutrals, are an important component of the dayside Martian upper atmosphere (e.g. Coates et al., 2011; Fox et al., 2008). The ionization process generates well-defined, unique features in the photoelectron energy distribution, characterized by several distinctive peaks at 22-27 eV related to the He II 30.4 nm line, which is the most intensive EUV emission line in the solar spectrum (e.g. Frahm et al., 2006b; 2006a). In addition, a reduction in photoelectron intensity occurs around 60-70 eV due to the rapid drop in solar radiation at wavelengths shorter than 17 nm (e.g. Peterson et al., 2016; Sakai et al., 2015). The above spectral features have been extensively observed over the past four decades (e.g.

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Section: Discussionmentioning

confidence: 99%

A Survey of Photoelectrons on the Nightside of Mars

Cao

Cui

et al. 2021

Geophysical Research Letters

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“…This means that the

{normalC normalO}_{2}^{+}

density should vary approximately with the CO 2 ‐to‐O density ratio multiplied by the solar ionizing flux, hereafter denoted as F [CO 2 ]/[O]. For the altitude range considered here, the Martian thermosphere is optically thin to EUV and X‐ray photons as both the photoionization rate and solar EUV heating rate peak at substantially lower altitudes (e.g., Hantsch & Bauer, 1990; Gu et al., 2020; Yao et al., 2019), which then implies that the change of the atmospheric column above during the GDS does not exert an influence. For further demonstration, we show in Figure 4b the variation of F [CO 2 ]/[O] as a function of L s , demonstrating a qualitatively similar trend during the GDS as in Figure 3b.…”

Section: Ionospheric Structure During the 2018 Global Dust Eventmentioning

confidence: 99%

Species‐dependent Response of the Martian Ionosphere to the 2018 Global Dust Event

Niu

Cui

et al. 2021

JGR Planets

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Dust storms are an outstanding phenomenon of the Martian climate, especially during spring and summer over the southern hemisphere (e.g., Zurek, 1982). When a dust storm occurs, a significant amount of dust particles are lifted upward into the atmosphere by wind-related processes. Given that dust is the major absorber of solar radiation in the atmosphere, the lifted dust particles can cause the lower atmosphere to expand and modify the global circulation patterns (e.g., Bougher et al., 1997; Heavens et al., 2011). Changes

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“…图 18 (网络版彩图) Gu等人 [78] 基于蒙特卡罗测试粒子实验得到的火星电离层O 一方面源于逃逸面温度对太阳紫外辐射的响应 [84,85,95,96] , 另一方面与火星高层大气H原子的产生途径密切相关--已有研究表明, 在一般情况下, H原子的产生来自CO 2 + 离子与H 2 分子的化学反应 [115,145] .…”

Section: H原子逃逸具有丰富的太阳周期变化性和季节变化性unclassified

Present-day atomic hydrogen escape on Mars and its variability

Cui¹,

Hao²,

Xu³

2022

Sci. Sin.-Phys. Mech. Astron.

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Atmospheric escape is one of the key factors controlling the evolution of Mars habitability. This topic has attracted extensive research interests over the past few decades and served as an important scientific object for several Mars missions. In early history, atmospheric escape on Mars was dominated by plasma escape; at present, neutral escape is probably more important. Escaping neutrals include atomic H, He, O, C, and N, the first of which is the lightest species in the Martian upper atmosphere and presumably undergoes easier escape. This study aims to provide a thorough review of the process of atomic H escape on Mars. In the present, such an escape mainly proceeds via thermal evaporation (Jeans escape), which is sensitive to the atomic H density and temperature at the Martian exobase and presents a range of exciting variabilities. Under normal conditions, atomic H is mainly produced via ionospheric chemistry, which drives H 2 dissociation. However, recent investigations have revealed that atomic H escape is substantially enhanced during global dust storms when low-altitude H 2 O can reach high altitude regions via vertical transport, accompanied by the release of H atoms from H 2 O dissociation via ionospheric chemistry. Despite the significant knowledge gained from existing studies, some questions remain to be solved, including (1) how the ideal Jeans formulism could reflect the actual behaviors of H escape on Mars, (2) whether or not the structure of the Martian H corona contains a nonthermal component, and (3) how H escape occurred in early history and how this affected the long-term evolution of the Martian climate.

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Neutral Heating Efficiency in the Dayside Martian Upper Atmosphere

Cited by 21 publications

References 135 publications

A Survey of Photoelectrons on the Nightside of Mars

A Survey of Photoelectrons on the Nightside of Mars

Species‐dependent Response of the Martian Ionosphere to the 2018 Global Dust Event

Present-day atomic hydrogen escape on Mars and its variability

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