Formation of a Possible Black-hole Ultracompact X-ray Binary with the Shortest Orbital Period

TL;DR

This paper proposes a new stellar evolution model with convection- and rotation-boosted magnetic braking that can explain the formation of a black-hole ultracompact X-ray binary with a 7.7-minute orbital period, matching recent observations.

Contribution

It demonstrates that the CARB magnetic braking model can produce BH UCXBs with shorter periods than standard models, providing a new formation pathway.

Findings

CARB MB model drives BH-MS binaries to 7.7-minute periods

Progenitor parameter space identified for future studies

Predicts detectable gravitational wave signals and tidal disruption events

Abstract

In the bulge of M31, the Chandra observations discovered a possible black hole (BH) ultracompact X-ray binary (UCXB) Seq.1 with an orbital period of 7.7 minutes and a maximum X-ray luminosity $L_{\rm X}=1.09^{+0.02}_{-0.01}\times10^{38}~ \rm erg\,s^{-1}$ in the $0.5-8$ keV band. The minimum orbital period of the BH UCXBs predicted by the standard magnetic braking (MB) model is longer than 8.3 minutes. In this work, we investigate whether the convection- and rotation-boosted (CARB) MB prescription can account for the formation of a BH UCXB like Seq.1. Our detailed stellar evolution models indicate that the CARB MB law can drive isolated BH-main sequence (MS) binaries to evolve toward BH UCXBs with an orbital period of $7.7~ \rm minutes$, in which a low-mass white dwarf transfers the material onto a BH in a short-term mass transfer episode, producing an X-ray luminosity of $10^{38}~\rm erg\,s^{-1}$. We also obtain an initial parameter space of BH-MS binaries as the progenitors of Seq.1 in the donor-star masses and orbital periods plane, which can be applied to future population synthesis simulations. If Seq.1 is indeed a BH UCXB, future spaceborne gravitational wave (GW) detectors can detect the low-frequency GW signals from this source, and a tidal disruption event will be expected after 0.12 Myr.