Methanol—A Poor Biosignature Gas in Exoplanet Atmospheres

Biosignature gas research has been growing in recent years thanks to next-generation space- and ground-based telescopes. Methanol (CH 3 OH) has many advantages as a biosignature gas candidate. First, CH 3 OH’s hydroxyl group (OH) has a unique spectral feature not present in other anticipated gases i...

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Veröffentlicht in:	The Astrophysical journal 2022-07, Vol.933 (1), p.6
Hauptverfasser:	Huang, Jingcheng, Seager, Sara, Petkowski, Janusz J., Zhan, Zhuchang, Ranjan, Sukrit
Format:	Artikel
Sprache:	eng
Schlagworte:	Astrobiology Astrophysics Atmosphere Biosignatures Carbon dioxide Dwarf stars Exoplanet atmospheres Extrasolar planets Extraterrestrial life Fluctuations Gases Hydroxyl groups James Webb Space Telescope Life on Earth Methanol Mixing ratio Organic carbon Planetary atmospheres Scale height Solar system Solubility Space telescopes Telescopes Terrestrial environments Terrestrial planets
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description	Biosignature gas research has been growing in recent years thanks to next-generation space- and ground-based telescopes. Methanol (CH 3 OH) has many advantages as a biosignature gas candidate. First, CH 3 OH’s hydroxyl group (OH) has a unique spectral feature not present in other anticipated gases in the atmospheres of rocky exoplanets. Second, there are no significant known abiotic CH 3 OH sources on terrestrial planets in the solar system. Third, life on Earth produces CH 3 OH in large quantities. However, despite CH 3 OH’s advantages, we consider it a poor biosignature gas in the atmospheres of terrestrial exoplanets due to the enormous production flux required to reach its detection limit. CH 3 OH’s high water solubility makes it very difficult to accumulate in the atmosphere. For the highly favorable planetary scenario of an exoplanet with an H 2 -dominated atmosphere orbiting an M5V dwarf star, we find that only when the column-averaged mixing ratio of CH 3 OH reaches at least 10 ppm can we detect it with the James Webb Space Telescope (JWST). The CH 3 OH bioproduction flux required to reach the JWST detection threshold of 10 ppm must be of the order of 10 14 molecules cm −2 s −1 , which is roughly three times the annual O 2 production on Earth. Considering that such an enormous flux of CH 3 OH is essentially a massive waste of organic carbon—a major building block of life, we think this flux, while mathematically possible, is likely biologically unattainable. Although CH 3 OH can theoretically accumulate on exoplanets with CO 2 - or N 2 -dominated atmospheres, such planets’ small atmospheric scale heights and weak atmospheric signals put them out of reach for near-term observations.
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Methanol (CH 3 OH) has many advantages as a biosignature gas candidate. First, CH 3 OH’s hydroxyl group (OH) has a unique spectral feature not present in other anticipated gases in the atmospheres of rocky exoplanets. Second, there are no significant known abiotic CH 3 OH sources on terrestrial planets in the solar system. Third, life on Earth produces CH 3 OH in large quantities. However, despite CH 3 OH’s advantages, we consider it a poor biosignature gas in the atmospheres of terrestrial exoplanets due to the enormous production flux required to reach its detection limit. CH 3 OH’s high water solubility makes it very difficult to accumulate in the atmosphere. For the highly favorable planetary scenario of an exoplanet with an H 2 -dominated atmosphere orbiting an M5V dwarf star, we find that only when the column-averaged mixing ratio of CH 3 OH reaches at least 10 ppm can we detect it with the James Webb Space Telescope (JWST). The CH 3 OH bioproduction flux required to reach the JWST detection threshold of 10 ppm must be of the order of 10 14 molecules cm −2 s −1 , which is roughly three times the annual O 2 production on Earth. Considering that such an enormous flux of CH 3 OH is essentially a massive waste of organic carbon—a major building block of life, we think this flux, while mathematically possible, is likely biologically unattainable. 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J</addtitle><description>Biosignature gas research has been growing in recent years thanks to next-generation space- and ground-based telescopes. Methanol (CH 3 OH) has many advantages as a biosignature gas candidate. First, CH 3 OH’s hydroxyl group (OH) has a unique spectral feature not present in other anticipated gases in the atmospheres of rocky exoplanets. Second, there are no significant known abiotic CH 3 OH sources on terrestrial planets in the solar system. Third, life on Earth produces CH 3 OH in large quantities. However, despite CH 3 OH’s advantages, we consider it a poor biosignature gas in the atmospheres of terrestrial exoplanets due to the enormous production flux required to reach its detection limit. CH 3 OH’s high water solubility makes it very difficult to accumulate in the atmosphere. For the highly favorable planetary scenario of an exoplanet with an H 2 -dominated atmosphere orbiting an M5V dwarf star, we find that only when the column-averaged mixing ratio of CH 3 OH reaches at least 10 ppm can we detect it with the James Webb Space Telescope (JWST). The CH 3 OH bioproduction flux required to reach the JWST detection threshold of 10 ppm must be of the order of 10 14 molecules cm −2 s −1 , which is roughly three times the annual O 2 production on Earth. Considering that such an enormous flux of CH 3 OH is essentially a massive waste of organic carbon—a major building block of life, we think this flux, while mathematically possible, is likely biologically unattainable. 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subjects	Astrobiology Astrophysics Atmosphere Biosignatures Carbon dioxide Dwarf stars Exoplanet atmospheres Extrasolar planets Extraterrestrial life Fluctuations Gases Hydroxyl groups James Webb Space Telescope Life on Earth Methanol Mixing ratio Organic carbon Planetary atmospheres Scale height Solar system Solubility Space telescopes Telescopes Terrestrial environments Terrestrial planets
title	Methanol—A Poor Biosignature Gas in Exoplanet Atmospheres
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