Localized Heating of the Martian Topside Ionosphere Through the Combined Effects of Magnetic Pumping by Large‐Scale Magnetosonic Waves and Pitch Angle Diffusion by Whistler Waves

Atmospheric escape is a fundamental process in the long-term habitability evolution of terrestrial planets. Recent observations on Mars have found the concurrence of the severe ionospheric erosion and the large-amplitude, quasi-perpendicular magnetosonic waves. However, whether and then how these magnetosonic waves had contributed to the ionospheric erosion remains unclear. Here we propose a new candidate mechanism, electron Landau heating by magnetosonic waves, for the Martian ionospheric erosion. In contrast to the cyclotron resonance with oxygen atomic and molecular ions above the escape energies, the magnetosonic waves Landau-resonate with the thermal electrons at energy channels of the order of 0.01-0.1 eV. Through the Landau resonance over tens of minutes, the large-amplitude (12 nT) magnetosonic waves can heat the topside ionospheric electrons to ∼2 times the normal temperature. The topside ionospheric electron heating could result in the enhancement of the ambipolar electric potential and eventually facilitate the escape of ionospheric plasma. Plain Language Summary An atmosphere of sufficient density is a fundamental condition for a habitable terrestrial planet. Mars as a terrestrial planet in the habitable zone of our solar system lost much of its atmosphere over billions of years and has thus become a unique testing ground to understand the planetary atmospheric loss processes. Recent observations on Mars have shown that the severe erosion of the ionosphere, an ionized part of the upper atmosphere, was accompanied by the large-amplitude, quasi-perpendicular magnetosonic waves. However, whether and then how these magnetosonic waves had contributed to the ionospheric erosion remains unclear. On the basis of space observations and numerical calculations, we propose a new physical mechanism, electron Landau heating by magnetosonic waves, for the Martian ionospheric erosion. The large-amplitude magnetosonic waves can heat the topside ionospheric electrons to ∼2 times the normal temperature over tens of minutes, enhance the ambipolar electric potential, and eventually facilitate the escape of ionospheric plasma. The electron Landau heating process may also contribute to the ionospheric erosion of other terrestrial planets within and beyond our solar system.

Section: Discussionmentioning

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Rapid Landau Heating of Martian Topside Ionospheric Electrons by Large‐Amplitude Magnetosonic Waves

Liu

Gao

et al. 2020

“…Electron acceleration events at Mars have been identified with measurements from MGS (e.g., Brain et al, 2006;Halekas et al, 2008), MEx (e.g., Leblanc et al, 2008), andMAVEN (e.g., Akbari et al, 2019;. The acceleration mechanisms include, but are not limited to, narrow electrostatic potential layers within double-layers (associated with inverted-V electron events) (e.g., Brain et al, 2006;, acceleration associated with current sheet crossings (e.g., Halekas et al, 2008;Harada et al, 2020), and wave-particle interaction (e.g., Fowler et al, 2020Fowler et al, , 2021. Meanwhile, upstream solar wind electron fluxes can be significantly increased during solar transient events such as interplanetary coronal mass ejections and stream interaction regions (e.g., Xu, Curry, et al, 2020).…”

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confidence: 99%

Empirically Determined Auroral Electron Events at Mars—MAVEN Observations

Mitchell

McFadden

et al. 2022

Self Cite

Discrete aurorae have been observed at magnetized planets such as Earth and Jupiter, triggered by accelerated electrons. Similar aurorae have also been observed at Mars with only localized strong crustal magnetisms. However, our understanding of this phenomenon at Mars is still limited. In particular, direct and quantitative comparisons of the auroral and its source electron events are lacking as these two types of observations are usually made at different times and/or locations. In this study, we establish empirical criteria to select electron events (“auroral electrons”) that could trigger detectable auroral emissions with Mars Atmosphere and Volatile EvolutioN measurements, thereby enabling a direct statistical comparison. We find auroral electrons share similar statistical characteristics to those previously reported for discrete auroral events. This study bridges the gap between electron observations and auroral detections and enables collaborations across different Mars missions, as well as comparative planetary studies of discrete aurora.

“…Above 250 km, the log of the densities are linearly extrapolated. The wave parameters used are representative of the observations by Harada et al (2016) and Fowler et al (2020). The wave power is assumed to be 10 −4 nT 2 /Hz.…”

Section: Model Configurationmentioning

confidence: 99%

Modeling Wave‐Particle Interactions With Photoelectrons on the Dayside Crustal Fields of Mars

Shane

Liemohn

2022

The unique and dynamic magnetic field environment of Mars offers a fascinating laboratory to study space physics. Crustal magnetic fields cover the surface of the planet and rotate in and out of interaction with the solar wind. The strongest crustal fields are in the southern hemisphere and have a structure similar to coronal arcades on the surface of the Sun. In between these mini-magnetospheres are cusp regions allowing the solar wind access to the upper atmosphere of Mars. A myriad of plasma processes have been studied on the crustal fields including magnetic reconnection (e.g.,