Local simulations of common-envelope dynamical inspiral. Impact of rotation, accretion, and stratification

TL;DR

This study uses local 3D hydrodynamic simulations to explore how rotation, stratification, and accretion influence small-scale gas dynamics, forces, and spin-up rates during common-envelope evolution, proposing revised force prescriptions.

Contribution

It introduces detailed local simulations incorporating rotation, stratification, and accretion effects, and proposes new semi-analytical models for drag and lift forces in common-envelope phases.

Findings

Stratification generates inward forces opposing outward lift.

Accretion prevents bubble formation around the companion.

Drag and lift are marginally affected by accretion.

Abstract

Common envelope evolution (CEE) is a crucial phase in binary stellar evolution. Current global three-dimensional simulations lack the resolution to capture the small-scale dynamics around the embedded companion, while local wind-tunnel simulations always approximate the companion's orbital motion as linear rather than as rotation around the center of mass. We investigate how rotation, accretion, and stratification influence small-scale gas dynamics, gravitational drag and lift forces, and the spin-up rate of the companion. We perform three-dimensional local hydrodynamic simulations of a $0.2\, M_\odot$ compact companion plunging into the envelope of a $2\, M_\odot$ red giant in a reference frame rotating at the companion's orbital angular velocity, using the Athena++ code. The presence of stratification generates an inward-directed force, partially opposed by a rotation-induced outward lift force. Both the resulting inward directed force and the drag force, strongly influenced by stratification, would affect the evolution of the binary separation. We propose revised semi-analytical prescriptions for both drag and lift forces. Without accretion and for sufficiently small gravitational softening radii, a quasi-hydrostatic bubble forms around the companion, while accretion prevents its formation and converts kinetic energy into heat that could contribute to the envelope ejection. Drag and lift forces are only marginally affected by accretion. The companion spin-up rate varies non-monotonically in time, first increasing and then decreasing as it plunges deeper into the envelope. These results motivate future magnetohydrodynamic simulations to investigate how accretion, rotation, and stratification affect magnetic amplification, and how magnetic fields, in turn, influence mass and angular momentum accretion rates, as well as the drag and lift force exerted on the companion.