Exploring the Relationships Between Exoplanet Orbital Architectures and Host Star Compositions
Additional Funding Sources
The project described was supported by the Pacific Northwest Louis Stokes Alliance for Minority Participation through the National Science Foundation under Award No. HRD-1410465.
Abstract
Gas giants with orbital periods below ten days are called, “hot Jupiters,” and one of the likely fates is for the planets to lose their atmospheres, leaving behind exposed, rocky and icy cores, — thereby contributing to another population of planets, ultra-short-period planets (USPs). Recent evidence suggests, however, that USPs might not arise from tidal disruption of hot Jupiter atmospheres after all, and the two classes of planets may instead be two different populations entirely. Using the bootstrap re-sampling method to randomly generate large samples of the two mentioned categories of planets and applying the Kolmogorov-Smirnov test to compare the metallicities of stars hosting each kind of planet, we hope to find what percentage of USPs, if any, are likely to be the rocky remains of hot Jupiters.
Exploring the Relationships Between Exoplanet Orbital Architectures and Host Star Compositions
Gas giants with orbital periods below ten days are called, “hot Jupiters,” and one of the likely fates is for the planets to lose their atmospheres, leaving behind exposed, rocky and icy cores, — thereby contributing to another population of planets, ultra-short-period planets (USPs). Recent evidence suggests, however, that USPs might not arise from tidal disruption of hot Jupiter atmospheres after all, and the two classes of planets may instead be two different populations entirely. Using the bootstrap re-sampling method to randomly generate large samples of the two mentioned categories of planets and applying the Kolmogorov-Smirnov test to compare the metallicities of stars hosting each kind of planet, we hope to find what percentage of USPs, if any, are likely to be the rocky remains of hot Jupiters.
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