On the effects of radiation on mass transfer in binary stars (2505.10616v1)

Abstract: Mass transfer (MT) in binary systems is a common evolutionary process that can significantly affect the structure, evolution, and final fate of both stars. In modeling MT hydrodynamics, it is usually assumed that the critical point of the flow, where the velocity exceeds the local sound speed, coincides with the inner Lagrange point (L1). However, in massive donors, radiative pressure dominates over gas pressure and the Eddington factor $\Gamma_\text{Edd}$ can reach or exceed unity. If there is significant momentum and/or energy exchange between gas and radiation, the critical point of the flow can shift away from L1, affecting the MT rate ($\dot{M}\text{d}$). Here, we investigate the effects of radiation on MT using time-steady radiative hydrodynamic equations and the assumption of the von Zeipel theorem. We provide analytical expressions that closely approximate $\dot{M}\text{d}$ and numerical solutions using a realistic equation of state. We find two main differences with respect to the traditional expressions for $\dot{M}\text{d}$. First, for Roche-lobe-underfilling donors with $\Gamma\text{Edd} \lesssim 1$, radiative momentum exchange leads to an exponential increase of $\dot{M}\text{d}$ as a function of $1-\Gamma\text{Edd}$. We provide a simple modification of existing prescriptions that takes this effect into account. Second, we find that the photon tiring limit for super-Eddington outflows is much less restrictive near L1 than in spherical stars. We suggest that donors with super-Eddington convectively inefficient subsurface layers are able to drive MT with $-\dot{M}\text{d} \gtrsim 10^{-2}\,\text{M}\odot\,\text{yr}^{-1}$ even before overfilling their Roche lobes. We characterize the conditions for this new mode of super-Eddington-boosted MT and discuss the implications for binary evolution including the potential link to nonterminal outbursts of Luminous Blue Variables.