Asteroseismic rotation rates of hot subdwarf B stars hint at transient accretion from leftover common envelope matter

Journal article

Asteroseismology enabled measuring the rotation rate in the deep stellar interiors of stars across several evolutionary phases, advancing the theory of angular momentum transport in single stars from the main sequence to the white dwarf phase. However, binary stellar evolution products have not yet been studied in the context of angular momentum transport constrained by asteroseismology. Hot subdwarf B (sdB) stars can pulsate in non-radial modes, enabling probing of their internal rotation. Those in binary systems form through mass transfer, thus they can be used to probe theories of internal rotation in post-mass-transfer stars. Here, we interpret observed asteroseismic core and envelope rotation rates of sdB stars in unsynchronized binary systems that formed through the common-envelope channel, using stellar evolution models of rotating sdB stars with internal magnetic fields. We find that when sdB stars form with the angular momentum content of red giant cores prior to common-envelope ejection, their predicted core rotation rates are 2–10 times lower than measured asteroseismic rotation rates, and their envelope rotation rates are lower by 2–5 orders of magnitude. This suggests that the angular momentum content of sdB stars increases during their formation. Since sdB stars in close binary systems may host circumstellar matter from a past common-envelope ejection, we show that if they accrete a small amount of matter, the combination of internal magnetic fields with angular momentum transfer through accretion spins up both the core and envelope to match their measured asteroseismic rotation rates.

Authors: Moyano, FD; Ge, H; Han, Z; Bordadágua, B; Uzundag, M

• Publication status: Published
• Peer review status: Peer reviewed
• Publisher: Oxford University Press
• Journal: Monthly Notices of the Royal Astronomical Society
• Volume: 548
• Issue: 4
• Pages: stag790
• Article number: stag790
• Publication date: 2026-04-27
• Acceptance date: 2026-04-13
• DOI: 10.1093/mnras/stag790
• EISSN: 1365-2966
• ISSN: 0035-8711
• Language: English
• Keywords: binaries: close; methods: numerical; asteroseismology; subdwarfs; stars: rotation; stars: evolution