Time-Incremented Multiscale Evolution (TIME): A Code-Independent Method for Time-Domain 3D Hydrodynamics and its Application to Roche Lobe Overflow

Abstract

Context. Many critical physical processes, such as Roche lobe overflow, strain modern simulation methods due to their durations and multidimensionality. Aims. We employ a novel method of time-domain multidimensional simulations to provide the first grid-based time domain 3D model of Roche lobe overflow using VH-1. Methods. Using a piecewise approach which alternates between high-resolution 3D dynamic modeling and computationally fast evolutionary modeling, we present and test a method capable of self-scaling variable time resolution at greatly reduced computational cost. Results. We find mass transfer in the test high mass x-ray binary M33 X-7 to be unstable and fully conservative in both mass and angular momentum transport onto the accretion disk beyond f >~ 1.01. This phase begins on thermal timescales and accelerates to span < 100 yrs beyond f >= 1.1, while the non-conservative stable phase of f <~ 1.01 occurs on roughly nuclear timescales. Conclusions. We identify a critical point f ~ 1.01 which terminates stable overflow, which may correspond to the point MdotL1 ~ Mdotwind or MdotL1 ~ 10-6 Msolar/yr in the general case.