THREE POSSIBLE ORIGINS FOR THE GAS LAYER ON GJ 1214b

We present an analysis of the bulk composition of the MEarth transiting super-Earth exoplanet GJ 1214b using planet interior structure models. We consider three possible origins for the gas layer on GJ 1214b: direct accretion of gas from the protoplanetary nebula, sublimation of ices, and outgassing from rocky material. Armed only with measurements of the planet mass (Mp = 6.55 ± 0.98 M ⊕), radius (Rp = 2.678 ± 0.13 R ⊕), and stellar irradiation level, our main conclusion is that we cannot infer a unique composition. A diverse range of planet interiors fits the measured planet properties. Nonetheless, GJ 1214b's relatively low average density (ρ p = 1870 ± 400 kg m–3) means that it almost certainly has a significant gas component. Our second major conclusion is that under most conditions we consider GJ 1214b would not have liquid water. Even if the outer envelope is predominantly sublimated water ice, the envelope will likely consist of a super-fluid layer sandwiched between vapor above and plasma (electrically conductive fluid) below at greater depths. In our models, a low intrinsic planet luminosity (2TW) is needed for a water envelope on GJ 1214b to pass through the liquid phase.

[1]  O. Grasset,et al.  A STUDY OF THE ACCURACY OF MASS–RADIUS RELATIONSHIPS FOR SILICATE-RICH AND ICE-RICH PLANETS UP TO 100 EARTH MASSES , 2009, 0902.1640.

[2]  S. Seager,et al.  A Computational Tool to Interpret the Bulk Composition of Solid Exoplanets based on Mass and Radius Measurements , 2008, 0808.1916.

[3]  I. Baraffe,et al.  Structure and evolution of super-Earth to super-Jupiter exoplanets - I. Heavy element enrichment in the interior , 2008, 0802.1810.

[4]  Xavier Bonfils,et al.  A super-Earth transiting a nearby low-mass star , 2009, Nature.

[5]  S. Saxena,et al.  Experimental vibrational Grüneisen ratio values for ϵ‐iron up to 330 GPa at 300 K , 2001 .

[6]  S. Seager,et al.  Ocean Planet or Thick Atmosphere: On the Mass-Radius Relationship for Solid Exoplanets with Massive Atmospheres , 2007, 0710.4941.

[7]  et al,et al.  The CoRoT space mission : early results Special feature Transiting exoplanets from the CoRoT space mission VIII . CoRoT-7 b : the first super-Earth with measured radius , 2009 .

[8]  W. Wagner,et al.  The IAPWS Formulation 1995 for the Thermodynamic Properties of Ordinary Water Substance for General and Scientific Use , 2002 .

[9]  Diana Valencia,et al.  Detailed Models of Super-Earths: How Well Can We Infer Bulk Properties? , 2007, 0704.3454.

[10]  H. Mizuno,et al.  Formation of the Giant Planets , 1980 .

[11]  R. Rafikov Atmospheres of Protoplanetary Cores: Critical Mass for Nucleated Instability , 2004, astro-ph/0405507.

[12]  S. Seager,et al.  Mass-Radius Relationships for Solid Exoplanets , 2007, 0707.2895.

[13]  Could we identify hot ocean-planets with CoRoT, Kepler and Doppler velocimetry? , 2007, astro-ph/0701608.

[14]  P. H. Hauschildt,et al.  Evolutionary models for cool brown dwarfs and extrasolar giant planets. The case of HD 209458 , 2003 .

[15]  H. F. Astrophysics,et al.  Internal structure of massive terrestrial planets , 2005, astro-ph/0511150.

[16]  L. Elkins‐Tanton Linked magma ocean solidification and atmospheric growth for Earth and Mars , 2008 .

[17]  Marc Ollivier,et al.  The CoRoT space mission : early results Special feature The CoRoT-7 planetary system : two orbiting super-Earths , 2009 .

[18]  Mark S. Marley,et al.  Planetary Radii across Five Orders of Magnitude in Mass and Stellar Insolation: Application to Transits , 2006 .

[19]  E. Gaidos,et al.  GEODYNAMICS AND RATE OF VOLCANISM ON MASSIVE EARTH-LIKE PLANETS , 2008, 0809.2305.

[20]  J. Beaulieu,et al.  Composition of Ices in Low-Mass Extrasolar Planets , 2008, 0804.0406.

[21]  M. Kuchner Volatile-rich Earth-Mass Planets in the Habitable Zone , 2003, astro-ph/0303186.

[22]  C. Oppenheimer 3.04 – Volcanic Degassing , 2003 .

[23]  Gilles Chabrier,et al.  An Equation of State for Low-Mass Stars and Giant Planets , 1995 .

[24]  H. Mao,et al.  Static compression of H2O-ice to 128 GPa (1.28 Mbar) , 1987, Nature.

[25]  M. Marley,et al.  Line and Mean Opacities for Ultracool Dwarfs and Extrasolar Planets , 2007, 0706.2374.

[26]  Eric W. Lemmon,et al.  Thermophysical Properties of Fluid Systems , 1998 .

[27]  R. Rosenfeld Nature , 2009, Otolaryngology--head and neck surgery : official journal of American Academy of Otolaryngology-Head and Neck Surgery.

[28]  S. Seager,et al.  A FRAMEWORK FOR QUANTIFYING THE DEGENERACIES OF EXOPLANET INTERIOR COMPOSITIONS , 2009, 0912.3288.

[29]  David J. Stevenson Special issue: Planetary diversity , 2007 .

[30]  B. Hansen On the Absorption and Redistribution of Energy in Irradiated Planets , 2008, 0801.2972.

[31]  C. Sotin,et al.  A new family of planets? Ocean-Planets , 2003 .

[32]  D. Sasselov,et al.  THE ATMOSPHERIC SIGNATURES OF SUPER-EARTHS: HOW TO DISTINGUISH BETWEEN HYDROGEN-RICH AND HYDROGEN-POOR ATMOSPHERES , 2008, 0808.1902.

[33]  Tristan Guillot THE INTERIORS OF GIANT PLANETS: Models and Outstanding Questions , 2001 .

[34]  David R. Alexander,et al.  Low-Temperature Opacities , 2005, astro-ph/0502045.

[35]  S. Seager,et al.  Ranges of Atmospheric Mass and Composition of Super-Earth Exoplanets , 2008 .

[36]  E. Salpeter,et al.  Theoretical high-pressure equations of state including correlation energy. , 1967 .

[37]  Y. Alibert,et al.  Bulk composition of the transiting hot Neptune around GJ 436 , 2009, 0904.2979.

[38]  A. D. Etangs,et al.  A diagram to determine the evaporation status of extrasolar planets , 2006, astro-ph/0609744.

[39]  CHEMISTRY OF SILICATE ATMOSPHERES OF EVAPORATING SUPER-EARTHS , 2009, 0906.1204.