Martian atmospheric hydrogen and deuterium: Seasonal changes and paradigm for escape to space

John T. Clarke; Majd Mayyasi; Dolon Bhattacharyya; Jean Yves Chaufray; Nicolas Schneider; Bruce Jakosky; Roger Yelle; Franck Montmessin; Michael Chaffin; Shannon Curry; Justin Deighan; Sonal Jain; Jean Loup Bertaux; Eryn Cangi; Matteo Crismani; Scott Evans; Sumedha Gupta; Franck Lefevre; Greg Holsclaw; Daniel Lo; William McClintock; Michael Stevens; Ian Stewart; Shane Stone; Paul Mahaffy; Mehdi Benna; Meredith Elrod

doi:10.1126/sciadv.adm7499

Martian atmospheric hydrogen and deuterium: Seasonal changes and paradigm for escape to space

John T. Clarke, Majd Mayyasi, Dolon Bhattacharyya, Jean Yves Chaufray, Nicolas Schneider, Bruce Jakosky, Roger Yelle, Franck Montmessin, Michael Chaffin, Shannon Curry, Justin Deighan, Sonal Jain, Jean Loup Bertaux, Eryn Cangi, Matteo Crismani, Scott Evans, Sumedha Gupta, Franck Lefevre, Greg Holsclaw, Daniel LoWilliam McClintock, Michael Stevens, Ian Stewart, Shane Stone, Paul Mahaffy, Mehdi Benna, Meredith Elrod

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Abstract

Mars’ water history is fundamental to understanding Earth-like planet evolution. Water escapes to space as atoms, and hydrogen atoms escape faster than deuterium giving an increase in the residual D/H ratio. The present ratio reflects the total water Mars has lost. Observations with the Mars Atmosphere and Volatile Evolution (MAVEN) and Hubble Space Telescope (HST) spacecraft provide atomic densities and escape rates for H and D. Large increases near perihelion observed each martian year are consistent with a strong upwelling of water vapor. Short-term changes require processes in addition to thermal escape, likely from atmospheric dynamics and superthermal atoms. Including escape from hot atoms, both H and D escape rapidly, and the escape fluxes are limited by resupply from the lower atmosphere. In this paradigm for the escape of water, the D/H ratio of the escaping atoms and the enhancement in water are determined by upwelling water vapor and atmospheric dynamics rather than by the specific details of atomic escape.

Original language	English (US)
Article number	eadm7499
Journal	Science Advances
Volume	10
Issue number	30
DOIs	https://doi.org/10.1126/sciadv.adm7499
State	Published - Jul 26 2024

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Clarke, J. T., Mayyasi, M., Bhattacharyya, D., Chaufray, J. Y., Schneider, N., Jakosky, B., Yelle, R., Montmessin, F., Chaffin, M., Curry, S., Deighan, J., Jain, S., Bertaux, J. L., Cangi, E., Crismani, M., Evans, S., Gupta, S., Lefevre, F., Holsclaw, G., ... Elrod, M. (2024). Martian atmospheric hydrogen and deuterium: Seasonal changes and paradigm for escape to space. Science Advances, 10(30), Article eadm7499. https://doi.org/10.1126/sciadv.adm7499

Clarke, JT, Mayyasi, M, Bhattacharyya, D, Chaufray, JY, Schneider, N, Jakosky, B, Yelle, R, Montmessin, F, Chaffin, M, Curry, S, Deighan, J, Jain, S, Bertaux, JL, Cangi, E, Crismani, M, Evans, S, Gupta, S, Lefevre, F, Holsclaw, G, Lo, D, McClintock, W, Stevens, M, Stewart, I, Stone, S, Mahaffy, P, Benna, M & Elrod, M 2024, 'Martian atmospheric hydrogen and deuterium: Seasonal changes and paradigm for escape to space', Science Advances, vol. 10, no. 30, eadm7499. https://doi.org/10.1126/sciadv.adm7499

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title = "Martian atmospheric hydrogen and deuterium: Seasonal changes and paradigm for escape to space",

abstract = "Mars{\textquoteright} water history is fundamental to understanding Earth-like planet evolution. Water escapes to space as atoms, and hydrogen atoms escape faster than deuterium giving an increase in the residual D/H ratio. The present ratio reflects the total water Mars has lost. Observations with the Mars Atmosphere and Volatile Evolution (MAVEN) and Hubble Space Telescope (HST) spacecraft provide atomic densities and escape rates for H and D. Large increases near perihelion observed each martian year are consistent with a strong upwelling of water vapor. Short-term changes require processes in addition to thermal escape, likely from atmospheric dynamics and superthermal atoms. Including escape from hot atoms, both H and D escape rapidly, and the escape fluxes are limited by resupply from the lower atmosphere. In this paradigm for the escape of water, the D/H ratio of the escaping atoms and the enhancement in water are determined by upwelling water vapor and atmospheric dynamics rather than by the specific details of atomic escape.",

author = "Clarke, {John T.} and Majd Mayyasi and Dolon Bhattacharyya and Chaufray, {Jean Yves} and Nicolas Schneider and Bruce Jakosky and Roger Yelle and Franck Montmessin and Michael Chaffin and Shannon Curry and Justin Deighan and Sonal Jain and Bertaux, {Jean Loup} and Eryn Cangi and Matteo Crismani and Scott Evans and Sumedha Gupta and Franck Lefevre and Greg Holsclaw and Daniel Lo and William McClintock and Michael Stevens and Ian Stewart and Shane Stone and Paul Mahaffy and Mehdi Benna and Meredith Elrod",

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AU - Clarke, John T.

AU - Mayyasi, Majd

AU - Bhattacharyya, Dolon

AU - Chaufray, Jean Yves

AU - Schneider, Nicolas

AU - Jakosky, Bruce

AU - Yelle, Roger

AU - Montmessin, Franck

AU - Chaffin, Michael

AU - Curry, Shannon

AU - Deighan, Justin

AU - Jain, Sonal

AU - Bertaux, Jean Loup

AU - Cangi, Eryn

AU - Crismani, Matteo

AU - Evans, Scott

AU - Gupta, Sumedha

AU - Lefevre, Franck

AU - Holsclaw, Greg

AU - Lo, Daniel

AU - McClintock, William

AU - Stevens, Michael

AU - Stewart, Ian

AU - Stone, Shane

AU - Mahaffy, Paul

AU - Benna, Mehdi

AU - Elrod, Meredith

PY - 2024/7/26

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N2 - Mars’ water history is fundamental to understanding Earth-like planet evolution. Water escapes to space as atoms, and hydrogen atoms escape faster than deuterium giving an increase in the residual D/H ratio. The present ratio reflects the total water Mars has lost. Observations with the Mars Atmosphere and Volatile Evolution (MAVEN) and Hubble Space Telescope (HST) spacecraft provide atomic densities and escape rates for H and D. Large increases near perihelion observed each martian year are consistent with a strong upwelling of water vapor. Short-term changes require processes in addition to thermal escape, likely from atmospheric dynamics and superthermal atoms. Including escape from hot atoms, both H and D escape rapidly, and the escape fluxes are limited by resupply from the lower atmosphere. In this paradigm for the escape of water, the D/H ratio of the escaping atoms and the enhancement in water are determined by upwelling water vapor and atmospheric dynamics rather than by the specific details of atomic escape.

AB - Mars’ water history is fundamental to understanding Earth-like planet evolution. Water escapes to space as atoms, and hydrogen atoms escape faster than deuterium giving an increase in the residual D/H ratio. The present ratio reflects the total water Mars has lost. Observations with the Mars Atmosphere and Volatile Evolution (MAVEN) and Hubble Space Telescope (HST) spacecraft provide atomic densities and escape rates for H and D. Large increases near perihelion observed each martian year are consistent with a strong upwelling of water vapor. Short-term changes require processes in addition to thermal escape, likely from atmospheric dynamics and superthermal atoms. Including escape from hot atoms, both H and D escape rapidly, and the escape fluxes are limited by resupply from the lower atmosphere. In this paradigm for the escape of water, the D/H ratio of the escaping atoms and the enhancement in water are determined by upwelling water vapor and atmospheric dynamics rather than by the specific details of atomic escape.

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Martian atmospheric hydrogen and deuterium: Seasonal changes and paradigm for escape to space

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