Abstract
AbstractThe present atmosphere of Venus contains almost no water, but recent measurements indicate that in its early history, Venus had an Earth‐like ocean. Understanding how the Venusian atmosphere evolved is important not only for Venus itself but also for understanding the evolution of other planetary atmospheres. In this study, we quantify the escape rates of oxygen ions from the present Venus to infer the past of the Venusian atmosphere. We show that an extrapolation of the current escape rates back in time leads to the total escape of 0.02–0.6 m of a global equivalent layer of water. This implies that the loss of ions to space, inferred from the present state, cannot account for the loss of an historical Earth‐like ocean. We find that the O+ escape rate increases with solar wind energy flux, where more energy available leads to a higher escape rate. Oppositely, the escape rate decreases slightly with increased extreme ultraviolet radiation (EUV) flux, though the small variation of EUV flux over the measured solar cycle may explain the weak dependency. These results indicate that there is not enough energy transferred from the solar wind to Venus' upper atmosphere that can lead to the escape of the atmosphere over the past 3.9 billion years. This means that the Venusian atmosphere did not have as much water in its atmosphere as previously assumed or the present‐day escape rates do not represent the historical escape rates at Venus. Otherwise, some other mechanisms have acted to more effectively remove the water from the Venusian atmosphere.
Highlights
Today, the Venusian atmosphere is thick and dry and has a high CO2 content, but it was likely different in its early history
The purpose of this study is to find an empirical relation between the escape and these upstream parameters, which we use for extrapolating the results backwards in time to calculate the total historical ion escape from the Venusian atmosphere
We have determined the current relation between the escape of O+ through the magnetotail of Venus and the upstream solar wind energy flux and solar extreme ultraviolet radiation (EUV) flux
Summary
The Venusian atmosphere is thick and dry and has a high CO2 content, but it was likely different in its early history. From measurements during 1979 to 1986, the electron altitude profiles in the nightside were determined to have an average density of 39 cm−3, which together with the estimated average ion velocity equivalent to 13 eV, gave an average escaping flux of 5·1025 O+/s, if the average was assumed for the entire disk of Venus (Brace et al, 1987). This number could be an overestimation, as Venus Express (VEx) measurements later showed that the flux is mainly located in the central magnetotail and near the boundary region (Barabash, Fedorov, et al, 2007). The purpose of this study is to find an empirical relation between the escape and these upstream parameters (section 3), which we use for extrapolating the results backwards in time to calculate the total historical ion escape from the Venusian atmosphere (section 4)
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