Abstract. Nonthermal processes such as dissociative recombination of ionosphenc molecules are known to lead to loss of atmospheric constituents (N, 0, C) at Mars where the gravitational potential is easily overcome by the energy imparted to the product atoms. Moreover, observations of escaping planetary ions on the PHOBOS-2 spacecraft showed that the solar wind is presently scavenging si~nificant amounts of both oxygen and molecular specIes as it flows past the planet. Because both the sun and the atmosphere of Mars have changed over time, the evolutionary importance of these processes cannot be estimated by simply multiplying the contemporary loss rates by the solar system age. Models of these loss mechanIsms must include consideration of ...
Because Mars does not have a strong intrinsic magnetic field, the atmosphere is eroded by interactio...
International audienceMars likely lost a significant part of its atmosphere to space during its hist...
International audienceIn November 2014 the MAVEN (Mars Atmosphere and Volatile EvolutioN) spacecraft...
The history of the martian atmosphere and climate over time cannot be properly understood without kn...
We examine the effects of the loss of Mars atmospheric constituents by solar-wind-induced sputtering...
This investigation concentrated on the question of how atmosphere escape, related to both photochemi...
In this study we analyze the non-thermal loss rates of O+, O-2(+) and CO2+ ions over the last 4.5 bi...
International audienceThis paper presents a new approach for calculating the sputtering of an atmosp...
Mars possesses no significant intrinsic magnetic field. The absence of magnetic protection allows t...
Present-day Mars is a cold and dry planet with a thin CO2-dominated atmosphere comprising only a few...
In the sputtering process an incident particle beam loses part of its energy to recoil motion of tar...
We discuss coupled ionosphere/thermosphere models of Mars and implications for the photochemical esc...
International audienceOne of the potential drivers of Mars' past atmospheric evolution is its escape...
Luhmann et al. recently suggested that sputtering of the Martian atmosphere by re-entering O(+) pick...
Because Mars does not have a strong intrinsic magnetic field, the atmosphere is eroded by interactio...
International audienceMars likely lost a significant part of its atmosphere to space during its hist...
International audienceIn November 2014 the MAVEN (Mars Atmosphere and Volatile EvolutioN) spacecraft...
The history of the martian atmosphere and climate over time cannot be properly understood without kn...
We examine the effects of the loss of Mars atmospheric constituents by solar-wind-induced sputtering...
This investigation concentrated on the question of how atmosphere escape, related to both photochemi...
In this study we analyze the non-thermal loss rates of O+, O-2(+) and CO2+ ions over the last 4.5 bi...
International audienceThis paper presents a new approach for calculating the sputtering of an atmosp...
Mars possesses no significant intrinsic magnetic field. The absence of magnetic protection allows t...
Present-day Mars is a cold and dry planet with a thin CO2-dominated atmosphere comprising only a few...
In the sputtering process an incident particle beam loses part of its energy to recoil motion of tar...
We discuss coupled ionosphere/thermosphere models of Mars and implications for the photochemical esc...
International audienceOne of the potential drivers of Mars' past atmospheric evolution is its escape...
Luhmann et al. recently suggested that sputtering of the Martian atmosphere by re-entering O(+) pick...
Because Mars does not have a strong intrinsic magnetic field, the atmosphere is eroded by interactio...
International audienceMars likely lost a significant part of its atmosphere to space during its hist...
International audienceIn November 2014 the MAVEN (Mars Atmosphere and Volatile EvolutioN) spacecraft...