Wind Accretion in Massive Binaries Experiencing High Mass Loss Rates: II. Eccentricity

TL;DR

This study uses numerical simulations to explore wind accretion in eccentric massive binaries during high mass-loss episodes, revealing how orbital parameters influence accretion efficiency and secondary star response.

Contribution

It introduces an analytical relation for accretion rates considering eccentricity, mass ratio, and mass-loss rates, and examines the secondary's thermal stability during intense wind accretion.

Findings

Accretion efficiency depends on orbital separation, eccentricity, and mass ratio.

Secondary star remains in thermal equilibrium despite accretion.

Wind mass loss from the companion reduces accretion efficiency.

Abstract

We perform numerical simulations to investigate high-power wind accretion in massive binary systems undergoing enhanced mass-loss episodes. The primary star is taken in the mass range $M_{1} = 60$--$90\,\mathrm{M_{\odot}}$, while the companion is a $30\,\mathrm{M_{\odot}}$ hot star. We model binary orbits with eccentricities of $e = 0$--$0.6$ and orbital periods of $P=455$--$1155$ days. We initiate strong eruptive events for the primary with mass-loss rates of $\dot{M}_{\rm w} = 10^{-2}$ -- $10^{-1}\,\rm{M_{\odot}~{yr}^{-1}}$, lasting for $1.5$ years. A fraction of the ejected wind material is accreted by the companion, with the accretion efficiency determined by the orbital separation, eccentricity, and stellar mass ratio. We analyze the resulting accretion rates and provide an analytical relation describing their dependence on the stellar mass ratio, mass-loss rate, and orbital parameters. We find that although the accretion modifies the stellar parameters of the secondary, the companion remains in thermal equilibrium and does not undergo significant radial expansion. We further include wind mass loss from the companion during wind accretion and find a substantial reduction in accretion efficiency compared to no wind scenario. For longer orbital periods, the models yield negative accretion rates, implying that any captured material is expelled or prevented from settling onto the accretor. These results provide new insight into the role of eccentric orbits and extreme mass-loss events in shaping the mass-transfer processes in massive binaries.