The Effect of Differential Limb Magnification on Abundance Analysis of Microlensed Dwarf Stars

TL;DR

This study examines how finite source effects during gravitational microlensing influence the spectral analysis of dwarf stars, finding that these effects cause minimal errors in atmospheric parameters and abundance measurements.

Contribution

The paper quantifies the impact of finite source effects on abundance analysis of microlensed dwarf stars, demonstrating that errors are generally small and often negligible.

Findings

Errors in effective temperature are less than 45K.

Errors in surface gravity are less than 0.1 dex.

Errors in abundance measurements are less than 0.06 dex.

Abstract

Finite source effects can be important in observations of gravitational microlensing of stars. Near caustic crossings, for example, some parts of the source star will be more highly magnified than other parts. The spectrum of the star is then no longer the same as when it is unmagnified, and measurements of the atmospheric parameters and abundances will be affected. The accuracy of abundances measured from spectra taken during microlensing events has become important recently because of the use of highly magnified dwarf stars to probe abundance ratios and the abundance distribution in the Galactic bulge. In this paper, we investigate the effect of finite source effects on spectra by using magnification profiles motivated by two events to synthesize spectra for dwarfs between 5000K to 6200K at solar metallicity. We adopt the usual techniques for analyzing the microlensed dwarfs, namely, spectroscopic determination of temperature, gravity, and microturbulent velocity, relying on equivalent widths. We find that ignoring the finite source effects for the more extreme case results in errors in Teff < 45K, in log g of <0.1 dex and in microturbulent velocity of <0.1 km/s. In total, changes in equivalent widths lead to small changes in atmospheric parameters and changes in abundances of <0.06 dex, with changes in [FeI/H] of <0.03 dex. For the case with a larger source-lens separation, the error in [FeI/H] is <0.01 dex. This latter case represents the maximum effect seen in events whose lightcurves are consistent with a point-source lens, which includes the majority of microlensed bulge dwarfs published so far.