Mars: Chemical weathering as a massive volatile sink

Photostimulated oxidation weathering irreversibly removes both oxygen and hydrogen from the atmosphere at a rate of 10⁸ to 10¹¹ cm^?2sec^?1. This corresponds to a net loss of 10²⁵ to 10²⁸ molecules cm^?2 (10² to 10⁵ g cm^?2 of H₂O, assuming a uniform rate over geologic time. Additional H₂O is removed through hydration of Fe₂O₃ and clay minerals, but the loss is reversible and the extent of regolith storage is uncertain. CO₂ is irreversibly removed from the atmosphere through the formation of CaCO₃ at a rate of 10⁷?10¹⁰cm^?2sec^?1. Over geologic time this corresponds to a net loss of 10²⁴?10²⁷ molecules cm^?2 (10¹?10⁴g cm^?2) of CO₂. Previously, it was proposed that exospheric escape was the principal irreversible volatile sink, amounting to only 10²g cm^?2 of H₂O and 10⁰g cm^?2 of CO₂ over geologic time. A recent tentative identification of abundant argon on Mars suggests that the planet may have degassed up to 10⁵g cm^?2 of H₂O and 10⁴g cm^?2 of CO₂. If the amounts of H₂O and CO₂ removed by photostimulated oxidation are close to the upper limits proposed here, it is possible that chemical weathering may have had a major effect on limiting the supply of H₂O and CO₂ trapped in the regolith and polar caps.