An Improved Method for Estimating the Masses of Stars with Transiting Planets

TL;DR

This paper introduces a new calibration method using stellar density (log rho) to accurately estimate the masses and radii of stars with transiting planets, improving reliability over traditional models.

Contribution

It develops a polynomial calibration using log rho, T_eff, and [Fe/H], validated with binary data and applied to SuperWASP stars, enhancing stellar parameter estimation accuracy.

Findings

Calibration with log rho yields accurate stellar masses and radii.

Mass estimates are robust against photometric uncertainties.

Good transit light curves are essential for precise radius determination.

Abstract

To determine the physical parameters of a transiting planet and its host star from photometric and spectroscopic analysis, it is essential to independently measure the stellar mass. This is often achieved by the use of evolutionary tracks and isochrones, but the mass result is only as reliable as the models used. The recent paper by Torres et al (2009) showed that accurate values for stellar masses and radii could be obtained from a calibration using T_eff, log g and [Fe/H]. We investigate whether a similarly good calibration can be obtained by substituting log rho - the fundamental parameter measured for the host star of a transiting planet - for log g, and apply this to star-exoplanet systems. We perform a polynomial fit to stellar binary data provided in Torres et al (2009) to obtain the stellar mass and radius as functions of T_eff, log rho and [Fe/H], with uncertainties on the fit produced from a Monte Carlo analysis. We apply the resulting equations to measurements for seventeen SuperWASP host stars, and also demonstrate the application of the calibration in a Markov Chain Monte Carlo analysis to obtain accurate system parameters where spectroscopic estimates of effective stellar temperature and metallicity are available. We show that the calibration using log rho produces accurate values for the stellar masses and radii; we obtain masses and radii of the SuperWASP stars in good agreement with isochrone analysis results. We ascertain that the mass calibration is robust against uncertainties resulting from poor photometry, although a good estimate of stellar radius requires good-quality transit light curve to determine the duration of ingress and egress.