The Nominal Ranges of Rocky Planet Masses, Radii, Surface Gravities, and Bulk Densities
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S. Desch | C. Unterborn | W. R. Panero | J. Haldemann | N. Hinkel | J. Schulze | W. Panero | A. Lorenzo
[1] P. Young,et al. A Concise Treatise on Converting Stellar Mass Fractions to Abundances to Molar Ratios , 2022, The Astronomical Journal.
[2] S. Kane,et al. Mantle Degassing Lifetimes through Galactic Time and the Maximum Age Stagnant-lid Rocky Exoplanets Can Support Temperate Climates , 2022, The Astrophysical Journal Letters.
[3] J. Steffen,et al. MAGRATHEA: an open-source spherical symmetric planet interior structure code , 2022, 2201.03094.
[4] C. Dorn,et al. Hidden Water in Magma Ocean Exoplanets , 2021, The Astrophysical Journal Letters.
[5] V. Adibekyan,et al. A compositional link between rocky exoplanets and their host stars , 2021, Science.
[6] Jennifer A. Johnson,et al. Analytic Estimates of the Achievable Precision on the Physical Properties of Transiting Planets Using Purely Empirical Measurements , 2021, The Astrophysical Journal.
[7] W. Benz,et al. AQUA: a collection of H2O equations of state for planetary models , 2020, 2009.10098.
[8] P. Tackley,et al. The influence of bulk composition on the long-term interior-atmosphere evolution of terrestrial exoplanets , 2020, Astronomy & Astrophysics.
[9] E. Cottrell,et al. The carbon content of Earth and its core , 2020, Proceedings of the National Academy of Sciences.
[10] G. Morard,et al. Carbon versus Other Light Elements in Earth’s Core , 2019, Deep Carbon.
[11] Joel Nothman,et al. SciPy 1.0-Fundamental Algorithms for Scientific Computing in Python , 2019, ArXiv.
[12] K. Hirose,et al. Melt–crystal density crossover in a deep magma ocean , 2019, Earth and Planetary Science Letters.
[13] F. Bouchy,et al. A giant impact as the likely origin of different twins in the Kepler-107 exoplanet system , 2019, Nature Astronomy.
[14] C. Dorn,et al. A new class of Super-Earths formed from high-temperature condensates: HD219134 b, 55 Cnc e, WASP-47 e , 2018, Monthly Notices of the Royal Astronomical Society.
[15] A. Bonomo,et al. Growth model interpretation of planet size distribution , 2018, Proceedings of the National Academy of Sciences.
[16] J. Bean,et al. Thorium in solar twins: implications for habitability in rocky planets , 2018, Monthly Notices of the Royal Astronomical Society.
[17] C. Lineweaver,et al. Enhanced constraints on the interior composition and structure of terrestrial exoplanets , 2018, Monthly Notices of the Royal Astronomical Society.
[18] S. Desch,et al. Updated Compositional Models of the TRAPPIST-1 Planets , 2018, Research Notes of the AAS.
[19] J. Brewer,et al. Spectral Properties of Cool Stars: Extended Abundance Analysis of Kepler Objects of Interest , 2018, The Astrophysical Journal Supplement Series.
[20] J. R. Rygg,et al. Crystal structure and equation of state of Fe-Si alloys at super-Earth core conditions , 2018, Science Advances.
[21] C. Unterborn,et al. The Star–Planet Connection. I. Using Stellar Composition to Observationally Constrain Planetary Mineralogy for the 10 Closest Stars , 2017, 1709.08630.
[22] G. Somers,et al. A Catalog of Stellar Unified Properties (CATSUP) for 951 FGK-Stars within 30 pc , 2017, 1709.04465.
[23] A. Dewaele,et al. Low temperature equation of state of iron , 2017 .
[24] S. Desch,et al. Inward migration of the TRAPPIST-1 planets as inferred from their water-rich compositions , 2017, 1706.02689.
[25] Howard Isaacson,et al. The California-Kepler Survey. III. A Gap in the Radius Distribution of Small Planets , 2017, 1703.10375.
[26] C. S. Fernandes,et al. Seven temperate terrestrial planets around the nearby ultracool dwarf star TRAPPIST-1 , 2017, Nature.
[27] D. Sasselov,et al. Metal-silicate Partitioning and Its Role in Core Formation and Composition on Super-Earths , 2017 .
[28] K. Hirose,et al. Persistence of strong silica-enriched domains in the Earth’s lower mantle , 2016, 1803.08026.
[29] P. Magain,et al. Temperate Earth-sized planets transiting a nearby ultracool dwarf star , 2016, Nature.
[30] F. Ryerson,et al. Core formation and core composition from coupled geochemical and geophysical constraints , 2015, Proceedings of the National Academy of Sciences.
[31] Y. Alibert,et al. Elemental ratios in stars vs planets (Research Note) , 2015, 1507.01343.
[32] P. Tackley,et al. Can we constrain the interior structure of rocky exoplanets from mass and radius measurements , 2015, 1502.03605.
[33] F. Timmes,et al. STELLAR ABUNDANCES IN THE SOLAR NEIGHBORHOOD: THE HYPATIA CATALOG , 2014, 1405.6719.
[34] K. von Braun,et al. The NASA Exoplanet Archive: Data and Tools for Exoplanet Research , 2013, 1307.2944.
[35] Y. Ohishi,et al. Thermoelastic properties of ice VII and its high-pressure polymorphs: Implications for dynamics of cold slab subduction in the lower mantle , 2010 .
[36] S. Seager,et al. A Computational Tool to Interpret the Bulk Composition of Solid Exoplanets based on Mass and Radius Measurements , 2008, 0808.1916.
[37] S. Seager,et al. Coreless Terrestrial Exoplanets , 2008, 0808.1908.
[38] S. Seager,et al. Mass-Radius Relationships for Solid Exoplanets , 2007, 0707.2895.
[39] Diana Valencia,et al. Detailed Models of Super-Earths: How Well Can We Infer Bulk Properties? , 2007, 0704.3454.
[40] D. Sasselov,et al. Radius and Structure Models of the First Super-Earth Planet , 2006, astro-ph/0610122.
[41] R. P. Butler,et al. The abundance distribution of stars with planets , 2006 .
[42] H. F. Astrophysics,et al. Internal structure of massive terrestrial planets , 2005, astro-ph/0511150.
[43] W. McDonough,et al. Compositional Model for the Earth's Core , 2003 .
[44] K. Lodders. Solar System Abundances and Condensation Temperatures of the Elements , 2003 .
[45] Forrest J. Rogers,et al. Updated and Expanded OPAL Equation-of-State Tables: Implications for Helioseismology , 2002 .
[46] Akira Kageyama,et al. Repeated and Sudden Reversals of the Dipole Field Generated by a Spherical Dynamo Action , 2002, Science.
[47] David P. Dobkin,et al. The quickhull algorithm for convex hulls , 1996, TOMS.
[48] H. Wänke,et al. Chemistry and accretion history of Mars , 1994, Philosophical Transactions of the Royal Society of London. Series A: Physical and Engineering Sciences.
[49] J. Poirier. Light elements in the Earth's outer core: A critical review , 1994 .
[50] H. Mao,et al. Thermal expansivity, bulk modulus, and melting curve of H2O–ice VII to 20 GPa , 1993 .
[51] J. Wasson,et al. Compositions of chondrites , 1988, Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences.
[52] Thorne Lay,et al. Core–mantle boundary heat flow , 2008 .