Gaia uncovers difference in B and Be star binarity at small scales: evidence for mass transfer causing the Be phenomenon

TL;DR

This study uses Gaia astrometry to compare binarity in B and Be stars, providing statistical evidence that binary interactions and inward migration of companions contribute to the Be star phenomenon.

Contribution

It offers the first statistical confirmation that binary interactions and companion migration within triples are key to the formation of Be stars, based on large-scale Gaia data analysis.

Findings

Similar binary fractions for B and Be stars at larger separations

Lower binary fraction for Be stars below 0.04" separation

Supports binary interaction and migration as causes of the Be phenomenon

Abstract

Be stars make up almost 20% of the B star population, and are rapidly rotating stars surrounded by a disc; however the origin of this rotation remains unclear. Mass transfer within close binaries provides the leading hypothesis, with previous detections of stripped companions to Be stars supporting this. Here, we exploit the exquisite astrometric precision of Gaia to carry out the largest to date comparative study into the binarity of matched samples of nearby B and Be stars from the Bright Star Catalogue. By utilising new "proper motion anomaly" values, derived from Gaia DR2 and DR3 astrometric data alongside previous values calculated using Hipparcos and Gaia data, and the Gaia provided RUWE, we demonstrate that we can identify unresolved binaries down to separations of 0.02". Using these measures, we find that the binary fractions of B and Be stars are similar between 0.04 - 10", but the Be binary fraction is significantly lower than that of the B stars for separations below 0.04". As the separation range of these "missing" binaries is too large for mass transfer, and stripped companions are not retrieved by these measures, we suggest the companions migrate inwards via binary hardening within a triple system. This confirms statistically for the first time the hypothesis that binary interaction causes the Be phenomenon, with migration causing the dearth of Be binaries between 0.02 - 0.04". Furthermore, we suggest that triplicity plays a vital role in this migration, and thus in the formation of Be stars as a whole.