To Be or not to Be: the role of rotation in modeling Galactic Be X-ray Binaries

Kyle Akira Rocha, Vicky Kalogera, Zoheyr Doctor, Jeff J. Andrews, Meng Sun, Seth Gossage, Simone S. Bavera, Tassos Fragos, Konstantinos Kovlakas, Matthias U. Kruckow, Devina Misra, Philipp M. Srivastava, Zepei Xing, Emmanouil Zapartas

Published 2024-03-11Version 1

Be X-ray binaries (Be-XRBs) are crucial in understanding high-mass X-ray binaries, featuring a rapidly rotating Be star and a neutron star companion in an eccentric orbit, intermittently accreting material from the Be star's decretion disk. Originating from binary stellar evolution, Be-XRBs are of significant interest to binary population synthesis (BPS) studies, encapsulating the physics of supernovae, common envelope, and mass transfer (MT). Using the POSYDON BPS code, employing pre-computed grids of detailed binary stellar evolution models, we investigate the Galactic Be-XRB population. POSYDON incorporates stellar rotation self-consistently during MT phases, enabling a detailed examination of the rotational distribution of Be stars. Our fiducial BPS and Be-XRB model align well with the orbital properties of Galactic Be-XRBs, emphasizing the role of rotational constraints. Our modeling reveals a bimodal rotational distribution of Be-XRB-like systems, in excellent agreement with literature values. All Be-XRBs undergo an MT phase before the first compact object forms, with over half experiencing a second MT phase from a stripped helium companion (Case BB). Computing rotationally-limited MT efficiencies and applying them to our population, we find that the majority of Be-XRBs have undergone highly non-conservative MT (beta ~ 0.15). Our study underscores the importance of detailed angular momentum modeling during MT in interpreting Be-XRB populations, emphasizing this population as a key probe for the stability and efficiency of MT in interacting binaries.