A gap in the double white dwarf separation distribution caused by the common-envelope evolution: astrometric evidence from Gaia

Abstract

The trajectory of the center of light of an unresolved binary is different from that of its center of mass. Binary-induced stellar centroid wobbling can therefore be detected as an excess in the goodness-of-fit of the single-star astrometric model. We use reduced 2 of the astrometric fit in the Gaia Early Data Release 3 to detect the likely unresolved double white dwarfs (DWDs). Using parallax-based distances we convert the excess of reduced 2 into the amplitude of the centroid wobble δ a, which is proportional to the binary separation a. The measured δ a distribution drops towards larger wobble amplitudes and shows a break around δ a ≈ 0.2 where it steepens. The integral of the distribution yields DWD fraction of 6.5 3.7 per cent in the range 0.01 < a (au) < 2. Using synthetic models of the Galactic DWDs we demonstrate that the break in the δ a distribution corresponds to one side of a deep gap in the DWD separation distribution at around a≈ 1 au. Model DWDs with separations less than several au shrink dramatically due to (al least one) common envelope phase, reshaping the original separation distribution, clearing a gap and creating a pile-up of systems with a≈ 0.01 au and δ a < 0.01. Our models reproduce the overall shape of the observed δ a distribution and its normalisation, however the predicted drop in the numbers of DWDs beyond the break is steeper than in the data.