Journal
ASTROPHYSICAL JOURNAL
Volume 795, Issue 1, Pages -Publisher
IOP PUBLISHING LTD
DOI: 10.1088/0004-637X/795/1/65
Keywords
planets and satellites: atmospheres; planets and satellites: interiors; planets and satellites: physical evolution
Categories
Funding
- Chinese Academy of Sciences
- Max-Planck-Gesellschaft
- National Natural Science Foundation of China [11273068, 11473073]
- Natural Science Foundation of Jiangsu Province [BK20141509]
- innovative and interdisciplinary program by CAS [KJZD-EW-Z001]
- Foundation of Minor Planets of the Purple Mountain Observatory
- Strategic Priority Research Program-The Emergence of Cosmological Structures of the Chinese Academy of Sciences [XDB09000000]
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We apply hydrodynamic evaporation models to different synthetic planet populations that were obtained from a planet formation code based on the core-accretion paradigm. We investigated the evolution of the planet populations using several evaporation models, which are distinguished by the driving force of the escape flow (X-ray or EUV), the heating efficiency in energy-limited evaporation regimes, or both. Although the mass distribution of the planet populations is barely affected by evaporation, the radius distribution clearly shows a break at approximately 2R(circle plus). We find that evaporation can lead to a bimodal distribution of planetary sizes and to an evaporation valley running diagonally downward in the orbital distance-planetary radius plane, separating bare cores from low-mass planets that have kept some primordial H/He. Furthermore, this bimodal distribution is related to the initial characteristics of the planetary populations because low-mass planetary cores can only accrete small primordial H/He envelopes and their envelope masses are proportional to their core masses. We also find that the population-wide effect of evaporation is not sensitive to the heating efficiency of energy-limited description. However, in two extreme cases, namely without evaporation or with a 100% heating efficiency in an evaporation model, the final size distributions show significant differences; these two scenarios can be ruled out from the size distribution of Kepler candidates.
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