Three regimes of extrasolar planet radius inferred from host star metallicities

Approximately half of the extrasolar planets (exoplanets) with radii less than four Earth radii are in orbits with short periods. Despite their sheer abundance, the compositions of such planets are largely unknown. The available evidence suggests that they range in composition from small, high-density rocky planets to low-density planets consisting of rocky cores surrounded by thick hydrogen and helium gas envelopes. Here we report the metallicities (that is, the abundances of elements heavier than hydrogen and helium) of more than 400 stars hosting 600 exoplanet candidates, and find that the exoplanets can be categorized into three populations defined by statistically distinct (∼4.5σ) metallicity regions. We interpret these regions as reflecting the formation regimes of terrestrial-like planets (radii less than 1.7 Earth radii), gas dwarf planets with rocky cores and hydrogen–helium envelopes (radii between 1.7 and 3.9 Earth radii) and ice or gas giant planets (radii greater than 3.9 Earth radii). These transitions correspond well with those inferred from dynamical mass estimates, implying that host star metallicity, which is a proxy for the initial solids inventory of the protoplanetary disk, is a key ingredient regulating the structure of planetary systems.

[1]  S. Tremaine,et al.  The excitation of density waves at the Lindblad and corotation resonances by an external potential. , 1979 .

[2]  P. Bodenheimer,et al.  Orbital migration of the planetary companion of 51 Pegasi to its present location , 1996, Nature.

[3]  G. González The stellar metallicity—giant planet connection , 1997 .

[4]  CRITICAL PROTOPLANETARY CORE MASSES IN PROTOPLANETARY DISKS AND THE FORMATION OF SHORT-PERIOD GIANT PLANETS , 1999, astro-ph/9903310.

[5]  Chemical analysis of 8 recently discovered extra-solar planet host stars , 2000, astro-ph/0009182.

[6]  Towards Better Age Estimates for Stellar Populations : The Y 2 Isochrones for Solar Mixture , 2001 .

[7]  Y.-W. Lee,et al.  Toward Better Age Estimates for Stellar Populations: The Y2 Isochrones for Solar Mixture , 2001 .

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

[9]  Shigeru Ida,et al.  Toward a Deterministic Model of Planetary Formation. II. The Formation and Retention of Gas Giant Planets around Stars with a Range of Metallicities , 2004, astro-ph/0408019.

[10]  J. Valenti,et al.  The Planet-Metallicity Correlation , 2005 .

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

[12]  D. Queloz,et al.  Spectroscopic parameters for 451 stars in the HARPS GTO planet search program - Stellar [Fe/H] and the frequency of exo-Neptunes , 2008, 0805.4826.

[13]  R. Nelson,et al.  On the formation of hot Neptunes and super-Earths , 2009, 0910.5299.

[14]  K. Cunha,et al.  STELLAR PARAMETERS AND METALLICITIES OF STARS HOSTING JOVIAN AND NEPTUNIAN MASS PLANETS: A POSSIBLE DEPENDENCE OF PLANETARY MASS ON METALLICITY , 2010, 1007.2681.

[15]  Austin,et al.  KEPLER'S FIRST ROCKY PLANET: KEPLER-10b , 2011, 1102.0605.

[16]  B. Hansen,et al.  MIGRATION THEN ASSEMBLY: FORMATION OF NEPTUNE-MASS PLANETS INSIDE 1 AU , 2011, 1105.2050.

[17]  Instituto de Astrof'isica de Canarias,et al.  Spectroscopic stellar parameters for 582 FGK stars in the HARPS volume-limited sample. Revising the metallicity-planet correlation , 2011, 1108.5279.

[18]  Jon M. Jenkins,et al.  ARCHITECTURE AND DYNAMICS OF KEPLER'S CANDIDATE MULTIPLE TRANSITING PLANET SYSTEMS , 2011, 1102.0543.

[19]  M. Holman,et al.  IMPROVED SPECTROSCOPIC PARAMETERS FOR TRANSITING PLANET HOSTS , 2012, 1208.1268.

[20]  J. B. Laird,et al.  An abundance of small exoplanets around stars with a wide range of metallicities , 2012, Nature.

[21]  F. Fressin,et al.  THE FALSE POSITIVE RATE OF KEPLER AND THE OCCURRENCE OF PLANETS , 2013, 1301.0842.

[22]  G. Laughlin,et al.  The minimum-mass extrasolar nebula: in situ formation of close-in super-Earths , 2012, 1211.1673.

[23]  Las Cumbres Observatory Global Telescope Network,et al.  PLANETARY CANDIDATES OBSERVED BY KEPLER. III. ANALYSIS OF THE FIRST 16 MONTHS OF DATA , 2012, 1202.5852.

[24]  P. Szkody,et al.  SPECTROSCOPY OF FAINT KEPLER MISSION EXOPLANET CANDIDATE HOST STARS , 2013, 1305.0578.

[25]  Howard Isaacson,et al.  ALL SIX PLANETS KNOWN TO ORBIT KEPLER-11 HAVE LOW DENSITIES , 2013, 1303.0227.

[26]  James E. Owen,et al.  KEPLER PLANETS: A TALE OF EVAPORATION , 2013, 1303.3899.

[27]  B. Hansen,et al.  TESTING IN SITU ASSEMBLY WITH THE KEPLER PLANET CANDIDATE SAMPLE , 2013, 1301.7431.

[28]  J. Fortney,et al.  UNDERSTANDING THE MASS–RADIUS RELATION FOR SUB-NEPTUNES: RADIUS AS A PROXY FOR COMPOSITION , 2013, 1311.0329.

[29]  G. Marcy,et al.  THE MASS–RADIUS RELATION FOR 65 EXOPLANETS SMALLER THAN 4 EARTH RADII , 2013, 1312.0936.

[30]  S. Raymond,et al.  No universal minimum-mass extrasolar nebula: evidence against in situ accretion of systems of hot super-Earths , 2014, 1401.3743.

[31]  M. R. Haas,et al.  MASSES, RADII, AND ORBITS OF SMALL KEPLER PLANETS: THE TRANSITION FROM GASEOUS TO ROCKY PLANETS , 2014, 1401.4195.

[32]  T. Guillot,et al.  A reassessment of the in situ formation of close-in super-Earths , 2015, 1504.03237.