Methane Clathrates in the Solar System

We review the reservoirs of methane clathrates that may exist in the different bodies of the Solar System. Methane was formed in the interstellar medium prior to having been embedded in the protosolar nebula gas phase. This molecule was subsequently trapped in clathrates that formed from crystalline...

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Published in:Astrobiology
Main Authors: Mousis, Olivier, Chassefiere, Eric, Holm, Nils G., Bouquet, Alexis, Waite, Jack Hunter, Geppert, Wolf Dietrich, Picaud, Sylvain, Aikawa, Yuri, Ali-dib, Mohamad, Charlou, Jean-luc, Rousselot, Philippe
Format: Article in Journal/Newspaper
Language:English
Published: Mary Ann Liebert, Inc 2015
Subjects:
Ice
permafrost
Online Access:https://archimer.ifremer.fr/doc/00266/37718/41116.pdf
https://doi.org/10.1089/ast.2014.1189
https://archimer.ifremer.fr/doc/00266/37718/
id ftarchimer:oai:archimer.ifremer.fr:37718
record_format openpolar
spelling ftarchimer:oai:archimer.ifremer.fr:37718 2023-05-15T16:37:56+02:00 Methane Clathrates in the Solar System Mousis, Olivier Chassefiere, Eric Holm, Nils G. Bouquet, Alexis Waite, Jack Hunter Geppert, Wolf Dietrich Picaud, Sylvain Aikawa, Yuri Ali-dib, Mohamad Charlou, Jean-luc Rousselot, Philippe 2015-04 application/pdf https://archimer.ifremer.fr/doc/00266/37718/41116.pdf https://doi.org/10.1089/ast.2014.1189 https://archimer.ifremer.fr/doc/00266/37718/ eng eng Mary Ann Liebert, Inc https://archimer.ifremer.fr/doc/00266/37718/41116.pdf doi:10.1089/ast.2014.1189 https://archimer.ifremer.fr/doc/00266/37718/ 2012 Mary Ann Liebert, Inc. publishers. All rights reserved, USA and worldwide info:eu-repo/semantics/openAccess restricted use Astrobiology (1531-1074) (Mary Ann Liebert, Inc), 2015-04 , Vol. 15 , N. 4 , P. 308-326 text Publication info:eu-repo/semantics/article 2015 ftarchimer https://doi.org/10.1089/ast.2014.1189 2021-09-23T20:26:12Z We review the reservoirs of methane clathrates that may exist in the different bodies of the Solar System. Methane was formed in the interstellar medium prior to having been embedded in the protosolar nebula gas phase. This molecule was subsequently trapped in clathrates that formed from crystalline water ice during the cooling of the disk and incorporated in this form into the building blocks of comets, icy bodies, and giant planets. Methane clathrates may play an important role in the evolution of planetary atmospheres. On Earth, the production of methane in clathrates is essentially biological, and these compounds are mostly found in permafrost regions or in the sediments of continental shelves. On Mars, methane would more likely derive from hydrothermal reactions with olivine-rich material. If they do exist, martian methane clathrates would be stable only at depth in the cryosphere and sporadically release some methane into the atmosphere via mechanisms that remain to be determined. In the case of Titan, most of its methane probably originates from the protosolar nebula, where it would have been trapped in the clathrates agglomerated by the satellite's building blocks. Methane clathrates are still believed to play an important role in the present state of Titan. Their presence is invoked in the satellite's subsurface as a means of replenishing its atmosphere with methane via outgassing episodes. The internal oceans of Enceladus and Europa also provide appropriate thermodynamic conditions that allow formation of methane clathrates. In turn, these clathrates might influence the composition of these liquid reservoirs. Finally, comets and Kuiper Belt Objects might have formed from the agglomeration of clathrates and pure ices in the nebula. The methane observed in comets would then result from the destabilization of clathrate layers in the nuclei concurrent with their approach to perihelion. Thermodynamic equilibrium calculations show that methane-rich clathrate layers may exist on Pluto as well. Key Words: Methane clathrate-Protosolar nebula-Terrestrial planets-Outer Solar System. Article in Journal/Newspaper Ice permafrost Archimer (Archive Institutionnelle de l'Ifremer - Institut français de recherche pour l'exploitation de la mer) Astrobiology 15 4 308 326
institution Open Polar
collection Archimer (Archive Institutionnelle de l'Ifremer - Institut français de recherche pour l'exploitation de la mer)
op_collection_id ftarchimer
language English
description We review the reservoirs of methane clathrates that may exist in the different bodies of the Solar System. Methane was formed in the interstellar medium prior to having been embedded in the protosolar nebula gas phase. This molecule was subsequently trapped in clathrates that formed from crystalline water ice during the cooling of the disk and incorporated in this form into the building blocks of comets, icy bodies, and giant planets. Methane clathrates may play an important role in the evolution of planetary atmospheres. On Earth, the production of methane in clathrates is essentially biological, and these compounds are mostly found in permafrost regions or in the sediments of continental shelves. On Mars, methane would more likely derive from hydrothermal reactions with olivine-rich material. If they do exist, martian methane clathrates would be stable only at depth in the cryosphere and sporadically release some methane into the atmosphere via mechanisms that remain to be determined. In the case of Titan, most of its methane probably originates from the protosolar nebula, where it would have been trapped in the clathrates agglomerated by the satellite's building blocks. Methane clathrates are still believed to play an important role in the present state of Titan. Their presence is invoked in the satellite's subsurface as a means of replenishing its atmosphere with methane via outgassing episodes. The internal oceans of Enceladus and Europa also provide appropriate thermodynamic conditions that allow formation of methane clathrates. In turn, these clathrates might influence the composition of these liquid reservoirs. Finally, comets and Kuiper Belt Objects might have formed from the agglomeration of clathrates and pure ices in the nebula. The methane observed in comets would then result from the destabilization of clathrate layers in the nuclei concurrent with their approach to perihelion. Thermodynamic equilibrium calculations show that methane-rich clathrate layers may exist on Pluto as well. Key Words: Methane clathrate-Protosolar nebula-Terrestrial planets-Outer Solar System.
format Article in Journal/Newspaper
author Mousis, Olivier
Chassefiere, Eric
Holm, Nils G.
Bouquet, Alexis
Waite, Jack Hunter
Geppert, Wolf Dietrich
Picaud, Sylvain
Aikawa, Yuri
Ali-dib, Mohamad
Charlou, Jean-luc
Rousselot, Philippe
spellingShingle Mousis, Olivier
Chassefiere, Eric
Holm, Nils G.
Bouquet, Alexis
Waite, Jack Hunter
Geppert, Wolf Dietrich
Picaud, Sylvain
Aikawa, Yuri
Ali-dib, Mohamad
Charlou, Jean-luc
Rousselot, Philippe
Methane Clathrates in the Solar System
author_facet Mousis, Olivier
Chassefiere, Eric
Holm, Nils G.
Bouquet, Alexis
Waite, Jack Hunter
Geppert, Wolf Dietrich
Picaud, Sylvain
Aikawa, Yuri
Ali-dib, Mohamad
Charlou, Jean-luc
Rousselot, Philippe
author_sort Mousis, Olivier
title Methane Clathrates in the Solar System
title_short Methane Clathrates in the Solar System
title_full Methane Clathrates in the Solar System
title_fullStr Methane Clathrates in the Solar System
title_full_unstemmed Methane Clathrates in the Solar System
title_sort methane clathrates in the solar system
publisher Mary Ann Liebert, Inc
publishDate 2015
url https://archimer.ifremer.fr/doc/00266/37718/41116.pdf
https://doi.org/10.1089/ast.2014.1189
https://archimer.ifremer.fr/doc/00266/37718/
genre Ice
permafrost
genre_facet Ice
permafrost
op_source Astrobiology (1531-1074) (Mary Ann Liebert, Inc), 2015-04 , Vol. 15 , N. 4 , P. 308-326
op_relation https://archimer.ifremer.fr/doc/00266/37718/41116.pdf
doi:10.1089/ast.2014.1189
https://archimer.ifremer.fr/doc/00266/37718/
op_rights 2012 Mary Ann Liebert, Inc. publishers. All rights reserved, USA and worldwide
info:eu-repo/semantics/openAccess
restricted use
op_doi https://doi.org/10.1089/ast.2014.1189
container_title Astrobiology
container_volume 15
container_issue 4
container_start_page 308
op_container_end_page 326
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