Metal-Rich M-dwarf Planet Hosts: Metallicities with K-Band Spectra

TL;DR

This paper presents a new, accessible method to estimate M-dwarf star metallicities using moderate-resolution K-band spectra, aiding in identifying promising exoplanet host stars more efficiently.

Contribution

It introduces an empirical metallicity indicator based on spectral line strengths that is accurate and easier to obtain than previous methods.

Findings

The indicator achieves an accuracy of +/- 0.15 dex.

It confirms that M-dwarf planet hosts tend to be metal-rich.

The method is applicable to stars with near-solar metallicities.

Abstract

A metal-rich environment facilitates planet formation, making metal-rich stars the most favorable targets for surveys seeking to detect new exoplanets. Using this advantage to identify likely low-mass planet hosts, however, has been difficult: until now, methods to determine M-dwarf metallicities required observationally expensive data (such as parallaxes and high-resolution spectra), and were limited to a few bright cool stars. We have obtained moderate (R~2700) resolution K-band spectra of 17 M-dwarfs with metallicity estimates derived from their FGK companions. Analysis of these spectra, and inspection of theoretical synthetic spectra, reveal that an M-dwarf's metallicity can be inferred from the strength of its Na I doublet (2.206 {\mu}m & 2.209 {\mu}m) and Ca I triplet (2.261 {\mu}m, 2.263 {\mu}m & 2.265 {\mu}m) absorption lines. We use these features, and a temperature-sensitive water index, to construct an empirical metallicity indicator applicable for M-dwarfs with near-solar metallicities (-0.5<[Fe/H]<+0.5). This indicator has an accuracy of +/- 0.15 dex, comparable to that of existing techniques for estimating M-dwarf metallicities, but is more observationally accessible, requiring only a moderate resolution K-band spectrum. Applying this method to 8 known M-dwarf planet hosts, we estimate metallicities ([Fe/H]) in excess of the mean metallicity of M-dwarfs in the solar neighborhood, consistent with the metallicity distribution of FGK planet hosts.