Study of Globular Cluster M53: new variables, distance, metallicity

TL;DR

This study analyzes variable stars in globular cluster M53 to determine its physical parameters, discovering new variables, refining distance estimates, and examining metallicity discrepancies using photometric and analytical methods.

Contribution

It introduces new variable star identifications in M53 and refines the cluster's distance and metallicity measurements using advanced photometric and analytical techniques.

Findings

12 new variable stars identified, including RR Lyrae and SX Phe types.

Distance modulus of M53 determined as 16.31 mag, consistent with LMC distance.

Metallicity from RRab Fourier analysis is higher than literature values, indicating calibration issues.

Abstract

We study the variable star content of the globular cluster M53 to compute the physical parameters of the constituting stars and the distance of the cluster. Covering two adjacent seasons in 2007 and 2008, new photometric data are gathered for 3048 objects in the field of M53. By using the OIS method and subsequently TFA, we search for variables in the full sample by using DFT and BLS methods. We select variables based on the statistics related to these methods combined with visual inspections. We identified 12 new variables (2 RR Lyrae stars, 7 short periodic stars - 3 of them are SX Phe stars - and 3 long-period variables). No eclipsing binaries were found in the present sample. Except for the 3 (hitherto unknown) Blazhko RR Lyrae stars, no multiperiodic variables were found. We showed that after proper period shift, the PLC relation for the first overtone RR Lyrae sample tightly follows the one spanned by the fundamental stars. Furthermore, the slope is in agreement with the one derived from other clusters. Based on the earlier Baade-Wesselink calibration of the PLC relations, the derived reddening-free distance modulus of M53 is 16.31 +/- 0.04 mag, corresponding to a distance modulus of 18.5 mag for the Large Magellanic Cloud. From the Fourier parameters of the RRab stars we obtained an average iron abundance of -1.58 +/- 0.03. This is ~0.5 dex higher than the overall abundance of the giants as given in the literature and derived in this paper from the three-color photometry of giants. We suspect that the source of this discrepancy (observable also in other, low-metallicity clusters) is the want of sufficient number of low-metallicity objects in the calibrating sample of the Fourier method.