Journey to the center of the common envelope evolution. Inner dynamics of the post-dynamical inspiral
Abstract
Three-dimensional hydrodynamical simulations of common envelope evolution are often terminated soon after the initial dynamical plunge of the companion transitions into a long-lasting post-dynamical inspiral with slowly varying semi-major axis, ab. This premature termination is often due to insufficient numerical resolution and challenges associated with the softening of the gravitational potential of the two cores. In this work, we use statically-refined 3D hydrodynamical simulations to study binaries orbiting inside a common envelope, exploring the effects of varying numerical resolution, δ, gravitational potential softening prescriptions, and the associated softening lengthscale, ε. We find that quantities such as the binary inspiral timescale or the volume-averaged shearing rate typically converge to asymptotic values only for ε 0.1 ab and δ 6 × 10-3ab with smaller ε requiring correspondingly smaller δ. After a few tens of binary orbits, the two cores become surrounded by a corotating, nearly hydrostatic gas structure, resembling the shared envelope of a contact binary. We propose that this structure is responsible for the slowing down of the dynamical inspiral, leading to an asymptotic inspiral timescale of approximately 105 orbital periods for a binary mass ratio q=1/3, and approximately 106 orbital periods for a binary mass ratio q=1. By investigating kinetic helicity, we argue that the magnetic field is unlikely to organize into large-scale structures via the usual α--effect during the post-dynamical phase. Even in the absence of magnetic fields, we observe intermittent polar outflows collimated by partially centrifugally evacuated polar funnels. (abridged)
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