Accurate dynamical mass determination of a classical Cepheid in an eclipsing binary system

TL;DR

This paper reports the discovery of a classical Cepheid in an eclipsing binary system in the Large Magellanic Cloud, enabling a precise one-percent dynamical mass measurement that confirms pulsation theory's accuracy.

Contribution

It provides the first accurate dynamical mass measurement of a classical Cepheid in an eclipsing binary, resolving the Cepheid mass discrepancy problem.

Findings

Dynamical mass determined with 1% precision

Mass agrees with pulsation mass, validating pulsation theory

First detection of a classical Cepheid in an eclipsing binary

Abstract

Stellar pulsation theory provides a means of determining the masses of pulsating classical Cepheid supergiant - it is the pulsation that causes their luminosity to vary. Such pulsational masses are found to be smaller than the masses derived from stellar evolution theory: this is the Cepheid mass discrepancy problem, for which a solution is missing. An independent, accurate dynamical mass determination for a classical Cepheid variable star (as opposed to type-II Cepheids, low-mass stars with a very different evolutionary history) in a binary system is needed in order to determine which is correct. The accuracy of previous efforts to establish a dynamical Cepheid mass from Galactic single-lined noneclipsing binaries was typically about 15-30 per cent, which is not good enough to resolve the mass discrepancy problem. In spite of many observational efforts, no firm detection of a classical Cepheid in an eclipsing double-lined binary has hitherto been reported. Here we report the discovery of a classical Cepheid in a well detached, double-lined eclipsing binary in the Large Magellanic Cloud. We determine the mass to a precision of one per cent and show that it agrees with its pulsation mass, providing strong evidence that pulsation theory correctly and precisely predicts the masses of classical Cepheids