Investigating the Atmospheric Mass Loss of the Kepler-105 Planets   Straddling the Radius Gap

Aaron Householder; Lauren M. Weiss; James E. Owen; Howard Isaacson,; Andrew W. Howard; Daniel Fabrycky; Leslie A. Rogers; Hilke E. Schlichting,; Benjamin J. Fulton; Erik A. Petigura; Steven Giacalone; Joseph M. Akana; Murphy; Corey Beard; Ashley Chontos; Fei Dai; Judah Van Zandt; Jack Lubin,; Malena Rice; Alex S. Polanski; Paul Dalba; Sarah Blunt; Emma V. Turtelboom,; Ryan Rubenzahl; Casey Brinkman

arXiv:2309.11494·astro-ph.EP·December 7, 2023

Investigating the Atmospheric Mass Loss of the Kepler-105 Planets Straddling the Radius Gap

Aaron Householder, Lauren M. Weiss, James E. Owen, Howard Isaacson,, Andrew W. Howard, Daniel Fabrycky, Leslie A. Rogers, Hilke E. Schlichting,, Benjamin J. Fulton, Erik A. Petigura, Steven Giacalone, Joseph M. Akana, Murphy, Corey Beard, Ashley Chontos, Fei Dai, Judah Van Zandt

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TL;DR

This study investigates the atmospheric mass loss of Kepler-105 planets near the radius gap, using RVs and TTVs to measure their masses, supporting photoevaporation as a key process in shaping their atmospheres.

Contribution

It provides the first combined RV and TTV analysis of Kepler-105, measuring planetary masses that support photoevaporation as a primary factor in the radius gap.

Findings

01

Kepler-105b is more massive than Kepler-105c despite being closer to the star.

02

Mass measurements suggest photoevaporation could explain the atmospheric differences in 76% of scenarios.

03

Other mechanisms like core-powered mass loss may also influence the planets' atmospheres.

Abstract

An intriguing pattern among exoplanets is the lack of detected planets between approximately $1.5$ R $_{\oplus}$ and $2.0$ R $_{\oplus}$ . One proposed explanation for this "radius gap" is the photoevaporation of planetary atmospheres, a theory that can be tested by studying individual planetary systems. Kepler-105 is an ideal system for such testing due to the ordering and sizes of its planets. Kepler-105 is a sun-like star that hosts two planets straddling the radius gap in a rare architecture with the larger planet closer to the host star ( $R_{b} = 2.53 \pm 0.07$ R $_{\oplus}$ , $P_{b} = 5.41$ days, $R_{c} = 1.44 \pm 0.04$ R $_{\oplus}$ , $P_{c} = 7.13$ days). If photoevaporation sculpted the atmospheres of these planets, then Kepler-105b would need to be much more massive than Kepler-105c to retain its atmosphere, given its closer proximity to the host star. To test this hypothesis, we simultaneously analyzed…

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Taxonomy

TopicsStellar, planetary, and galactic studies · Astronomy and Astrophysical Research · Astrophysics and Star Formation Studies