Survey for Distant Solar Twins (SDST) -- I. EPIC method for stellar parameter measurement

TL;DR

This paper introduces EPIC, a new efficient method for measuring stellar parameters from medium-resolution spectra to identify solar twins and analogues at large distances, expanding the known solar twin population.

Contribution

The paper presents EPIC, a novel differential EW-based approach for stellar parameter determination suitable for low S/N spectra of distant stars observed with AAT/HERMES.

Findings

EPIC achieves small uncertainties in stellar parameters at S/N=25.

It enables identification of solar twins up to 4 kpc away.

The method is optimized for Sun-like stars with medium-resolution spectra.

Abstract

Solar twins are stars of key importance to the field of astronomy and offer a multitude of science applications. Only a small number ($\lesssim200$) of solar twins are known today, all of which are relatively close to our Sun ($\lesssim800\,pc$). The goal of our Survey for Distant Solar Twins (SDST) is to identify many more solar twin and solar analogue stars out to much larger distances ($\sim4\,kpc$). In this paper, we present a new method to identify solar twins using relatively low $S/N$, medium resolving power ($R\sim 28{,}000$) spectra that will be typical of such distant targets observed with HERMES on the $3.9\,m$ Anglo-Australian Telescope (AAT). We developed a novel approach, namely EPIC, to measure stellar parameters which we use to identify stars similar to our Sun. EPIC determines the stellar atmospheric parameters (effective temperature $T_{\mathrm{eff}}$, surface gravity $\log g$ and metallicity [Fe/H]) using differential equivalent width (EW) measurements of selected spectroscopic absorption features and a simple model, trained on previously analysed spectra, that connects these EWs to the stellar parameters. The reference for the EW measurements is a high $S/N$ solar spectrum which is used to minimise several systematic effects. EPIC is fast, optimised for Sun-like stars and yields stellar parameter measurements with small enough uncertainties to enable spectroscopic identification of solar twin and analogue stars up to $\sim4\,kpc$ away using AAT/HERMES, i.e.\ $\sigma\left(T_{\mathrm{eff}}, \log g, \textrm{[Fe/H]}\right) = \left(50\,K, 0.08\,dex, 0.03\,dex\right)$ on average at $S/N=25$.