Spectroscopic characterisation of gravitationally lensed stars at high redshifts

TL;DR

This study assesses the feasibility of spectroscopic observations of gravitationally lensed stars at high redshifts using JWST and ELT, identifying key spectral features and their dependence on stellar properties.

Contribution

It provides the first detailed analysis of detectable spectral lines in high-redshift lensed stars with upcoming telescopes, considering various stellar parameters and observational constraints.

Findings

UV spectral lines are most detectable for hot stars (T_eff ≥ 15,000 K).

C IV and Si IV lines are prominent at T_eff=30,000 K.

Lower temperature stars show detectable calcium H- and K-lines.

Abstract

Deep imaging of galaxy cluster fields have in recent years revealed tens of candidates for gravitationally lensed stars at redshifts $z\approx$ 1-6, and future searches are expected to reveal highly magnified stars from even earlier epochs. Multi-band photometric observations may be used to constrain the redshift, effective temperature $T_\mathrm{eff}$ and dust attenuation along the line of sight to such objects. When combined with an estimate of the likely magnification, these quantities may be converted into a constraint on the stellar luminosity and, for an adopted set of stellar evolutionary tracks, the initial stellar mass. Further characterization is, however, difficult without spectroscopic observations, which at the typical brightness levels of high-redshift lensed stars becomes extremely challenging for even the largest existing telescopes. Here, we explore what spectral features one can realistically hope to detect in lensed stars with peak brightness in the range 26-28 AB mag, $T_\mathrm{eff}=$ 4000-50 000 K and redshifts $z=$1-10, using spectroscopy with the James Webb Space Telescope (JWST) and the forthcoming Extremely Large Telescope. We find that a majority of detectable lines appear in the rest UV-range for stars with $T_\mathrm{eff}\geq$15 000 K. The strongest detectable spectral lines are the C IV $\lambda$ 1550 \r{A} line and the Si IV $\lambda\lambda$1393, 1403 \r{A}-doublet at $T_\mathrm{eff}=$30 000 K. For lower temperatures, the calcium H- and K-lines at $T_\mathrm{eff}=$6000 K are among the most readily detectable. In limited wavelength ranges, ELT is expected to provide more sensitive spectroscopic observations, and with higher resolution than JWST. We find that variations of both mass loss rate and metallicity lead to noticeable effects in the detectability of certain spectral lines with both JWST and ELT.