Induced Core Formation Time in Subcritical Magnetic Clouds by Large-Scale Trans-Alfv\'enic Flows

TL;DR

This paper presents a semi-analytical formula for core formation time in subcritical magnetic clouds, showing that large-scale flows significantly accelerate collapse by enhancing ambipolar diffusion, with results supported by 2D MHD simulations.

Contribution

The study derives a semi-analytical formula linking flow speed to core formation time, clarifying the physical process of turbulence-induced acceleration in magnetic cloud collapse.

Findings

Core formation time inversely proportional to the square of flow speed above Alfvén speed.

Turbulence can shorten core formation time by about three times.

Semi-analytical formula matches numerical simulation results.

Abstract

We clarify the mechanism of accelerated core formation by large-scale nonlinear flows in subcritical magnetic clouds by finding a semi-analytical formula for the core formation time and describing the physical processes that lead to them. Recent numerical simulations show that nonlinear flows induce rapid ambipolar diffusion that leads to localized supercritical regions that can collapse. Here, we employ non-ideal magnetohydrodynamic simulations including ambipolar diffusion for gravitationally stratified sheets threaded by vertical magnetic fields. One of the horizontal dimensions is eliminated, resulting in a simpler two-dimensional simulation that can clarify the basic process of accelerated core formation. A parameter study of simulations shows that the core formation time is inversely proportional to the square of the flow speed when the flow speed is greater than the Alfv\'en speed. We find a semi-analytical formula that explains this numerical result. The formula also predicts that the core formation time is about three times shorter than that with no turbulence, when the turbulent speed is comparable to the Alfv\'en speed.