Assessing the Habitability of the TRAPPIST-1 System Using a 3D Climate Model

The TRAPPIST-1 system provides an extraordinary opportunity to study multiple terrestrial extrasolar planets and their atmospheres. Here we use the National Center for Atmospheric Research Community Atmosphere Model version 4 to study the possible climate and habitability of the planets in the TRAPPIST-1 system. We assume ocean-covered worlds, with atmospheres comprised of N2, CO2, and H2O, and with orbital and geophysical properties defined from observation. Model results indicate that the inner three planets (b, c, and d) presently reside interior to the inner edge of the traditional liquid water habitable zone. Thus if water ever existed on the inner planets, they would have undergone a runaway greenhouse and lost their water to space, leaving them dry today. Conversely the outer 3 planets (f, g, and h) fall beyond the maximum CO2 greenhouse outer edge of the habitable zone. Model results indicate that the outer planets cannot be warmed despite as much as 30 bar CO2 atmospheres, instead entering a snowball state. The middle planet (e) represents the best chance for a presently habitable ocean-covered world in the TRAPPIST-1 system. Planet e can maintain at least some habitable surface area with 0 - 2 bar CO2, depending on the background N2 content. Near present day Earth surface temperatures can be maintained for an ocean-covered planet e with either 1 bar N2 and 0.4 bar CO2, or a 1.3 bar pure CO2 atmosphere.

[1]  R. Luger,et al.  Extreme water loss and abiotic O2 buildup on planets throughout the habitable zones of M dwarfs. , 2014, Astrobiology.

[2]  Yongyun Hu,et al.  EFFECTS OF OBLIQUITY ON THE HABITABILITY OF EXOPLANETS AROUND M DWARFS , 2016 .

[3]  O. Toon,et al.  Controls on the Archean climate system investigated with a global climate model. , 2014, Astrobiology.

[4]  Dorian S. Abbot,et al.  Deciphering thermal phase curves of dry, tidally locked terrestrial planets , 2014 .

[5]  Aomawa L. Shields,et al.  Constraints on Climate and Habitability for Earth-like Exoplanets Determined from a General Circulation Model , 2017, 1702.03315.

[6]  Philip J. Rasch,et al.  A Comparison of the CCM3 Model Climate Using Diagnosed and Predicted Condensate Parameterizations , 1998 .

[7]  Norman H Sleep,et al.  Habitable zone limits for dry planets. , 2011, Astrobiology.

[8]  M. H. Hart,et al.  Habitable zones about main sequence stars , 1979 .

[9]  G. Danabasoglu,et al.  Climate Sensitivity of the Community Climate System Model, Version 4 , 2012 .

[10]  N. McFarlane,et al.  Sensitivity of Climate Simulations to the Parameterization of Cumulus Convection in the Canadian Climate Centre General Circulation Model , 1995, Data, Models and Analysis.

[11]  Dorian S. Abbot,et al.  STRONG DEPENDENCE OF THE INNER EDGE OF THE HABITABLE ZONE ON PLANETARY ROTATION RATE , 2014, 1404.4992.

[12]  Francois Forget,et al.  Increased insolation threshold for runaway greenhouse processes on Earth-like planets , 2013, Nature.

[13]  X. Delfosse,et al.  Habitable planets around the star Gliese 581 , 2007, 0710.5294.

[14]  Suvrath Mahadevan,et al.  THE INNER EDGE OF THE HABITABLE ZONE FOR SYNCHRONOUSLY ROTATING PLANETS AROUND LOW-MASS STARS USING GENERAL CIRCULATION MODELS , 2016, 1602.05176.

[15]  P. Magain,et al.  Temperate Earth-sized planets transiting a nearby ultracool dwarf star , 2016, Nature.

[16]  J. Marotzke,et al.  Transition to a Moist Greenhouse with CO2 and solar forcing , 2016, Nature Communications.

[17]  Steven C. Sherwood,et al.  An adaptability limit to climate change due to heat stress , 2010, Proceedings of the National Academy of Sciences.

[18]  R. Pierrehumbert,et al.  HYDROGEN GREENHOUSE PLANETS BEYOND THE HABITABLE ZONE , 2011, 1105.0021.

[19]  Aomawa L. Shields,et al.  The effect of host star spectral energy distribution and ice-albedo feedback on the climate of extrasolar planets. , 2013, Astrobiology.

[20]  R. Pierrehumbert,et al.  WATER LOSS FROM TERRESTRIAL PLANETS WITH CO2-RICH ATMOSPHERES , 2013, 1306.3266.

[21]  É. Bolmont,et al.  Water loss from terrestrial planets orbiting ultracool dwarfs: implications for the planets of TRAPPIST-1 , 2016, 1605.00616.

[22]  Dorian S. Abbot,et al.  STABILIZING CLOUD FEEDBACK DRAMATICALLY EXPANDS THE HABITABLE ZONE OF TIDALLY LOCKED PLANETS , 2013, 1307.0515.

[23]  D. Hunten The Escape of Light Gases from Planetary Atmospheres , 1973 .

[24]  Migration and the Formation of Systems of Hot Super-Earths and Neptunes , 2006, astro-ph/0609779.

[25]  Owen B. Toon,et al.  Delayed onset of runaway and moist greenhouse climates for Earth , 2014 .

[26]  Franck Selsis,et al.  3D climate modeling of close-in land planets: Circulation patterns, climate moist bistability and habitability , 2013, 1303.7079.

[27]  O. Toon,et al.  Hospitable archean climates simulated by a general circulation model. , 2013, Astrobiology.

[28]  Owen B. Toon,et al.  The evolution of habitable climates under the brightening Sun , 2015 .

[29]  Ignasi Ribas,et al.  The habitability of Proxima Centauri b II. Possible climates and Observability , 2016, 1608.06827.

[30]  Ryan C. Terrien,et al.  HABITABLE ZONES AROUND MAIN-SEQUENCE STARS: NEW ESTIMATES , 2013, 1301.6674.

[31]  Derek Homeier,et al.  Brown dwarfs , 2007, Scholarpedia.

[32]  D. Abbot,et al.  EFFECT OF SURFACE-MANTLE WATER EXCHANGE PARAMETERIZATIONS ON EXOPLANET OCEAN DEPTHS , 2016, The Astrophysical journal.

[33]  C. S. Fernandes,et al.  Seven temperate terrestrial planets around the nearby ultracool dwarf star TRAPPIST-1 , 2017, Nature.

[34]  J. Kasting,et al.  Habitable zones around main sequence stars. , 1993, Icarus.