The Globular Cluster NGC 5286. II. Variable Stars

TL;DR

This study identifies and analyzes 57 variable stars in globular cluster NGC 5286, revealing its Oosterhoff II classification and providing detailed light curves, periods, and physical parameters, with implications for its metallicity and distance.

Contribution

The paper reports the discovery of 57 variable stars in NGC 5286, including new RR Lyrae, and provides detailed period, light curve, and Fourier analysis, enhancing understanding of the cluster's properties.

Findings

NGC 5286 is classified as an Oosterhoff II globular cluster.

The cluster's RR Lyrae stars have a mean period of 0.656 days.

Derived distance modulus of (m-M)V = 16.04 mag.

Abstract

We present the results of a search for variable stars in the globular cluster NGC 5286, which has recently been suggested to be associated with the Canis Major dwarf spheroidal galaxy. 57 variable stars were detected, only 19 of which had previously been known. Among our detections one finds 52 RR Lyrae (22 RRc and 30 RRab), 4 LPV's, and 1 type II Cepheid of the BL Herculis type. Periods are derived for all of the RR Lyrae as well as the Cepheid, and BV light curves are provided for all the variables. The mean period of the RRab variables is <Pab> = 0.656 days, and the number fraction of RRc stars is N(c)/N(RR) = 0.42, both consistent with an Oosterhoff II (OoII) type -- thus making NGC 5286 one of the most metal-rich ([Fe/H] = -1.67; Harris 1996) OoII globulars known to date. The minimum period of the \RRab's, namely Pab,min = 0.513 d, while still consistent with an OoII classification, falls towards the short end of the observed Pab,min distribution for OoII globular clusters. As was recently found in the case of the prototypical OoII globular cluster M15 (NGC 7078), the distribution of stars in the Bailey diagram does not strictly conform to the previously reported locus for OoII stars. We provide Fourier decomposition parameters for all of the RR Lyrae stars detected in our survey, and discuss the physical parameters derived therefrom. The values derived for the RRc's are not consistent with those typically found for OoII clusters, which may be due to the cluster's relatively high metallicity -- the latter being confirmed by our Fourier analysis of the ab-type RR Lyrae light curves. We derive for the cluster a revised distance modulus of (m-M)V = 16.04 mag. (ABRIDGED)