A search for spectroscopic binaries in the galactic globular cluster M4. Based on 5973 individual spectra collected at VLT

TL;DR

This study conducted a multi-epoch high-resolution spectroscopic survey of the globular cluster M4, identifying binary star candidates, estimating the binary fraction, and analyzing their radial distribution within the cluster.

Contribution

It provides the first large spectroscopic binary candidate catalog for M4, measuring binary fractions inside and outside the core with high precision.

Findings

57 binary candidates identified from radial velocity variations.

Lower limit binary fraction of 3.0% in the cluster.

Binary fraction decreases from core to outer regions.

Abstract

We present a large multi-epoch high resolution spectroscopic investigation for the search of binary candidates in the Galactic Globular Cluster (GGC) M4. The aim of our work is the identification of the binary candidates, and the determination of the binary fraction and of the binary radial distribution. We present a large multi-epoch high resolution spectroscopic investigation for the search of binary candidates in the Galactic Globular Cluster (GGC) M4. The aim of our work is the identification of the binary candidates, and the determination of the binary fraction and of the binary radial distribution. The average radial velocity of the observed cluster members is $70.29+/-0.07(+/-0.3)(+/-0.1)km/s. The search for variations in radial velocities among the stars with multi-epoch observations yielded 57 binary star candidates. Our radial velocity measurement accuracy allowed us to identify at a 3sigma level binaries with radial velocity variations larger than ~0.3km/s for the target stars with V<15, and larger than ~0.5km/s for the targets with V>15. We identified 4 binary star candidates out of 97 observed targets inside the core radius, and 53 candidates out of 2372 observed stars outside the core radius. Accounting for the incompleteness affecting our survey, the lower limit for the total binary fraction is f=3.0+/-0.3%. The lower limit for the binary fraction in the cluster core is f=5.1+/-2.3%, while outside the core it decreases to f=3.0+/-0.4%. Similarly, we found f=4.5+/-0.4% and f=1.8+/-0.6% for the binary fraction inside and outside the half mass radius.