火星上层大气白天侧CO2++释放的观测

IF 2.9 3区 地球科学 Earth and Planetary Physics Pub Date : 2020-08-18 DOI:10.26464/epp2020036
Hao Gu, Jun Cui, DanDan Niu, LongKang Dai, JianPing Huang, XiaoShu Wu, YongQiang Hao, Yong Wei
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引用次数: 4

摘要

双电荷正离子(指示)是行星电离层的重要组成部分,因为它们的形成需要大量的能量。由于这些离子的丰度很低,对它们的观测异常困难;到目前为止,只检测到原子迹象。最近在火星大气和挥发物演化任务上进行的中性气体和离子质谱仪(NGIMS)测量为在行星高层大气中决定性地检测分子指示提供了第一次机会,在这种情况下是CO2 ++。NGIMS数据显示,日面平均CO2 ++分布从160 km处的5.6 cm−3稳步下降到200 km以上的1 cm−3以下。190km以下CO2的双光离和190km以上CO2 +的单光离是CO2 +的主要产生机制;CO2 ++的破坏主要是自然解离,但与大气CO2和O的反应在160 km以下变得重要。进行了简化的光化学模式计算,合理地再现了低海拔地区2倍的数据,但低估了高海拔地区4倍的数据。最后,我们报告了太阳对CO2 ++密度的控制要比对CO2 +密度的控制强得多。
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Observation of CO2++ dication in the dayside Martian upper atmosphere

Doubly charged positive ions (dications) are an important component of planetary ionospheres because of the large energy required for their formation. Observations of these ions are exceptionally difficult due to their low abundances; until now, only atomic dications have been detected. The Neutral Gas and Ion Mass Spectrometer (NGIMS) measurements made on board the recent Mars Atmosphere and Volatile Evolution mission provide the first opportunity for decisive detection of molecular dications, CO2 ++ in this case, in a planetary upper atmosphere. The NGIMS data reveal a dayside averaged CO2 ++ distribution declining steadily from 5.6 cm−3 at 160 km to below 1 cm−3 above 200 km. The dominant CO2 ++ production mechanisms are double photoionization of CO2 below 190 km and single photoionization of CO2 + at higher altitudes; CO2 ++ destruction is dominated by natural dissociation, but reactions with atmospheric CO2 and O become important below 160 km. Simplified photochemical model calculations are carried out and reasonably reproduce the data at low altitudes within a factor of 2 but underestimate the data at high altitudes by a factor of 4. Finally, we report a much stronger solar control of the CO2 ++ density than of the CO2 + density .

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Earth and Planetary Physics
Earth and Planetary Physics GEOSCIENCES, MULTIDISCIPLINARY-
自引率
17.20%
发文量
174
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