RR Lyrae From Binary Evolution: Abundant, Young and Metal-Rich

TL;DR

This study demonstrates that binary stellar evolution can naturally produce young, metal-rich RR Lyrae stars, challenging the traditional view that they are exclusively old and metal-poor, and aligns with observed properties.

Contribution

The paper introduces detailed binary evolution models showing how binary interactions create metal-rich RR Lyrae stars, explaining their presence in younger, metal-rich populations.

Findings

Binary interactions produce metal-rich RR Lyrae with diverse ages.

Galactic RR Lyrae from binary evolution are mainly young and in the Thin Disc and Bulge.

Binary-made RR Lyrae dominate the Solar Neighbourhood population.

Abstract

RR Lyrae are a well-known class of pulsating horizontal branch stars widely used as tracers of old, metal-poor stellar populations. However, mounting observational evidence shows that a significant fraction of these stars may be young and metal-rich. Here, through detailed binary stellar evolution modelling, we show that all such metal-rich RR Lyrae can be naturally produced through binary interactions. Binary companions of these RR Lyrae stars formed through binary interactions partly strip their progenitor's envelopes during a preceding red giant phase. As a result, stripped horizontal branch stars become bluer than their isolated stellar evolution counterparts and thus end up in the instability strip. In contrast, in the single evolution scenario, the stars can attain such colours only at large age and low metallicity. While binary-made RR Lyrae can possess any ages and metallicities, their Galactic population is relatively young (1 to 9 Gyr) and dominated by the Thin Disc and the Bulge. We show that Galactic RR Lyrae from binary evolution are produced at rates compatible with the observed metal-rich population and have consistent G-band magnitudes, Galactic kinematics and pulsation properties. Furthermore, these systems dominate the RR Lyrae population in the Solar Neighbourhood. We predict that all metal-rich RR Lyrae have an A, F, G or K-type companion with a long orbital period (P > 1000 d). Observationally characterising the orbital periods and masses of such stellar companions will provide valuable new constraints on mass and angular momentum-loss efficiency for Sun-like accretors and the nature of RR Lyrae populations.