Stellar Multiplicity Meets Stellar Evolution And Metallicity: The APOGEE View

TL;DR

This study uses APOGEE survey data to analyze stellar multiplicity across different evolutionary stages and metallicities, revealing how multiplicity fractions vary and impact binary formation and related phenomena.

Contribution

It provides the first large-scale statistical analysis of stellar multiplicity as a function of evolutionary phase and metallicity using APOGEE data.

Findings

Multiplicity fraction decreases from main sequence to red giant branch.

Metal-poor stars have 2-3 times higher multiplicity than metal-rich stars.

Multiplicity characteristics influence binary interaction rates and planetary habitability.

Abstract

We use the multi-epoch radial velocities acquired by the APOGEE survey to perform a large scale statistical study of stellar multiplicity for field stars in the Milky Way, spanning the evolutionary phases between the main sequence and the red clump. We show that the distribution of maximum radial velocity shifts (\drvm) for APOGEE targets is a strong function of \logg, with main sequence stars showing \drvm\ as high as $\sim$300 \kms, and steadily dropping down to $\sim$30 \kms\ for \logg$\sim$0, as stars climb up the Red Giant Branch (RGB). Red clump stars show a distribution of \drvm\ values comparable to that of stars at the tip of the RGB, implying they have similar multiplicity characteristics. The observed attrition of high \drvm\ systems in the RGB is consistent with a lognormal period distribution in the main sequence and a multiplicity fraction of 0.35, which is truncated at an increasing period as stars become physically larger and undergo mass transfer after Roche Lobe Overflow during H shell burning. The \drvm\ distributions also show that the multiplicity characteristics of field stars are metallicity dependent, with metal-poor ([Fe/H]$\lesssim-0.5$) stars having a multiplicity fraction a factor 2-3 higher than metal-rich ([Fe/H]$\gtrsim0.0$) stars. This has profound implications for the formation rates of interacting binaries observed by astronomical transient surveys and gravitational wave detectors, as well as the habitability of circumbinary planets.