Chemistry of atmospheres formed during accretion of the Earth and other terrestrial planets

TL;DR

This study models the chemical composition of atmospheres formed during planetary accretion, revealing how different types of chondritic materials influence atmospheric gases and their potential observability.

Contribution

It provides the first comprehensive prediction of atmospheric compositions during planetary accretion based on various chondritic materials using chemical equilibrium and kinetic calculations.

Findings

CI and CM chondrites produce H2O-rich atmospheres

Ordinary and high-iron enstatite chondrites yield H2-rich atmospheres

Low-iron enstatite chondrites produce CO-rich atmospheres

Abstract

We used chemical equilibrium and chemical kinetic calculations to model chemistry of the volatiles released by heating different types of carbonaceous, ordinary and enstatite chondritic material as a function of temperature and pressure. Our results predict the composition of atmospheres formed by outgassing during accretion of the Earth and other terrestrial planets. Outgassing of CI and CM carbonaceous chondritic material produces H2O-rich (steam) atmospheres in agreement with the results of impact experiments. However, outgassing of other types of chondritic material produces atmospheres dominated by other gases. Outgassing of ordinary (H, L, LL) and high iron enstatite (EH) chondritic material yields H2-rich atmospheres with CO and H2O being the second and third most abundant gases. Outgassing of low iron enstatite (EL) chondritic material gives a CO-rich atmosphere with H2, CO2, and H2O being the next most abundant gases. Outgassing of CV carbonaceous chondritic material gives a CO2-rich atmosphere with H2O being the second most abundant gas. Our results predict that the atmospheres formed during accretion of the Earth and Mars were probably H2-rich unless the accreted material was dominantly CI and CM carbonaceous chondritic material. We also predict significant amounts of S, P, Cl, F, Na, and K in accretionary atmospheres at high temperatures (1500-2500 K). Finally, our results may be useful for interpreting spectroscopic observations of accreting extrasolar terrestrial planets.