Comprehensive Comparison of Two Global Multis-Species MHD Models of Mars

IF 2.9 3区 地球科学 Q2 ASTRONOMY & ASTROPHYSICS
Wenyi Sun, Ryoya Sakata, Yingjuan Ma, Kanako Seki, Christopher T. Russell, Naoki Terada, Shotaro Sakai, Hiroyuki Shinagawa, David Brain, Gabor Toth
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Abstract

Understanding the interaction between Mars and the solar wind is crucial for comprehending the atmospheric evolution and climate change on Mars. To gain a comprehensive understanding of the Martian plasma environment, global numerical simulations are essential in addition to spacecraft observations. However, there are still discrepancies among different simulation models. This study investigates how these discrepancies stem from the considered physical processes and numerical implementations. We compare two global multispecies MHD models: the “Sun model” based on the BATS-R-US code and the “Sakata model” based on a newly developed multifluid model MAESTRO. By employing the same typical upstream conditions and the same neutral atmosphere for current Mars, along with similar numerical implementations such as inner boundary conditions, we obtain simulation results that exhibit unprecedented agreement between the two models. The dayside results are nearly identical, especially along the subsolar line, indicating the robustness of MHD models to predict dayside interaction under given upstream conditions and ionosphere assumptions. The escape rates of planetary ions are also in good agreement. However, discrepancies remain in the terminator and nightside regions. Detailed numerical implementations, including inner boundary conditions, magnetic field divergence control methods, and radial resolutions, are shown to influence certain aspects of the results greatly, such as magnetotail configuration and ion diffusion.

两种火星全球多物种 MHD 模型的综合比较
了解火星与太阳风之间的相互作用对于理解火星大气演变和气候变化至关重要。要全面了解火星等离子体环境,除了航天器观测之外,全球数值模拟也必不可少。然而,不同的模拟模型之间仍然存在差异。本研究探讨了这些差异如何源于所考虑的物理过程和数值实现。我们比较了两个全球多物种 MHD 模型:基于 BATS-R-US 代码的 "太阳模型 "和基于新开发的多流体模型 MAESTRO 的 "坂田模型"。通过采用相同的典型上游条件和当前火星的相同中性大气,以及类似的数值实现(如内边界条件),我们获得了两个模型之间前所未有的一致的模拟结果。日侧结果几乎完全相同,尤其是沿太阳系下线,这表明在给定的上游条件和电离层假设下,MHD 模型在预测日侧相互作用方面的稳健性。行星离子的逃逸率也非常一致。然而,在终结者和夜侧区域仍存在差异。详细的数值实现,包括内部边界条件、磁场发散控制方法和径向分辨率,都会对结果的某些方面产生很大影响,例如磁尾构造和离子扩散。
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来源期刊
Earth and Space Science
Earth and Space Science Earth and Planetary Sciences-General Earth and Planetary Sciences
CiteScore
5.50
自引率
3.20%
发文量
285
审稿时长
19 weeks
期刊介绍: Marking AGU’s second new open access journal in the last 12 months, Earth and Space Science is the only journal that reflects the expansive range of science represented by AGU’s 62,000 members, including all of the Earth, planetary, and space sciences, and related fields in environmental science, geoengineering, space engineering, and biogeochemistry.
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