The rotational behavior of Kepler Stars with Planets

TL;DR

This study measures the rotation periods of Kepler host stars, analyzes their angular momentum, and compares observations with theoretical models to enhance understanding of stellar rotation and star-planet angular momentum exchange.

Contribution

It provides new rotation period measurements for 63 stars and confirms the agreement between observed stellar rotation and theoretical predictions across a broad stellar mass range.

Findings

540 stars show significant rotational modulation

Rotation periods range from 2 to 89 days

Results support theoretical models of stellar angular momentum

Abstract

We analyzed the host stars of the present sample of confirmed planets detected by Kepler and Kepler Objects of Interest (KOI) to compute new photometric rotation periods and to study the behavior of their angular momentum. Lomb-Scargle periodograms and wavelet maps were computed for 3,807 stars. For 540 of these stars, we were able to detect rotational modulation of the light curves at a significance level of greater than 99%. For 63 of these 540 stars, no rotation measurements were previously available in the literature. According to the published masses and evolutionary tracks of the stars in this sample, the sample is composed of M- to F-type stars (with masses of 0.48-1.53 M$_{\odot}$) with rotation periods that span a range of 2 to 89 days. These periods exhibit an excellent agreement with previously reported (for the stars for which such values are available), and the observed rotational period distribution strongly agrees with theoretical predictions. Furthermore, for the 540 sources considered here, the stellar angular momentum provides an important test of Kraft's relation based on the photometric rotation periods. Finally, this study directly contributes in a direct approach to our understanding of how angular momentum is distributed between the host star and its (detected) planetary system; the role of angular momentum exchange in such systems is an unavoidable piece of the stellar rotation puzzle.