Non-thermal production and escape of OH from the upper atmosphere of Mars

TL;DR

This paper presents a theoretical analysis of non-thermal formation, excitation, and escape of OH molecules in Mars's upper atmosphere, highlighting their role in atmospheric escape and potential implications for planetary evolution.

Contribution

It introduces a detailed quantum-mechanical model of non-thermal OH production and escape mechanisms in Mars's atmosphere, incorporating energetic particle interactions and predicting emission spectra.

Findings

Estimated OH escape flux of about 5×10^{22} s^{-1}

Non-thermal OH contributes to Mars's hot corona

Mechanism applicable to other planetary atmospheres

Abstract

We present a theoretical analysis of formation and kinetics of hot OH molecules in the upper atmosphere of Mars produced in reactions of thermal molecular hydrogen and energetic oxygen atoms. Two major sources of energetic O considered are the photochemical production, via dissociative recombination of O$_{2}^{+}$ ions, and energizing collisions with fast atoms produced by the precipitating Solar Wind (SW) ions, mostly H$^+$ and He$^{2+}$, and energetic neutral atoms (ENAs) originating in the charge-exchange collisions between the SW ions and atmospheric gases. Energizing collisions of O with atmospheric secondary hot atoms, induced by precipitating SW ions and ENAs, are also included in our consideration. The non-thermal reaction O + H$_2(v,j) \rightarrow$ H + OH$(v',j')$ is described using recent quantum-mechanical state-to-state cross sections, which allow us to predict non-equilibrium distributions of excited rotational and vibrational states $(v',j')$ of OH and expected emission spectra. A fraction of produced translationally hot OH is sufficiently energetic to overcome Mars' gravitational potential and escape into space, contributing to the hot corona. We estimate the total escape flux from dayside of Mars for low solar activity conditions at about $5\times10^{22}$ s$^{-1}$, or about 0.1\% of the total escape rate of atomic O and H. The described non-thermal OH production mechanism is general and expected to contribute to the evolution of atmospheres of the planets, satellites, and exoplanets with similar atmospheric compositions.