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Discovery and characterization of K2 planets from the ground and space

Livingston, John-Henry 東京大学 DOI:10.15083/0002001881

2021.10.04

概要

The Kepler mission, launched by NASA in 2009, and its extended mission K2, have provided a trove of data unprecedented in both quality and quantity, which has opened new vistas to planet occurrence and diversity. The discovery of a large multitude of planetary systems dissimilar to our own also raised questions about long-held theories of planet formation and migration. From their birth in the protoplanetary disk, to migration and dynamical scattering, to atmospheric sculpting by radiation from the host star, planets undergo many physical changes, especially within their first billion years of existence. Instead of continuously monitoring the same star field, K2 has expanded the Kepler survey to a succession of fields along the ecliptic plane. This has enabled three important opportunities: 1) the discovery of planets orbiting bright stars, which are more amenable to detailed characterization;2) the discovery of planets orbiting stars with well determined ages, such as members of open clusters; and 3) the characterization of planets that challenge current theories of formation and migration, such as ultra-short-period planets. This thesis address all of these goals, by leveraging data from K2 and ground-based telescopes to discover planets en masse and address the following questions: Are the radii of young planets imprinted with any information about their formation? What is the timescale of atmospheric sculpting by photoevaporation? By what mechanism and over what timescale do ultra-short-period planets form? To explore this exciting new domain of planetary science and begin to answer these questions, we have used high-precision photometry from K2, reconnaissance imaging/spectroscopy and high-precision radial velocities from ground-based telescopes, and near- infrared transit observations with Spitzer. The primary results of this work are: 1) The discovery and validation of 112 new planets, including the first two transiting multi-planet cluster systems; 2) the measurement of planet mass/density, which constrains composition; and 3) space-based follow-up observations with Spitzer to measure precise planet radii and orbital ephemerides, enhancing their future characterization prospects with JWST.

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