The emergence of the Md-Macc correlation in the MHD wind scenario

TL;DR

This paper investigates how magnetohydrodynamic (MHD) winds can naturally produce the observed correlation between disk mass and accretion rate in proto-planetary disks, expanding understanding beyond specific initial conditions.

Contribution

It provides analytical expressions and conditions under which the Md-Macc correlation emerges in MHD wind-driven accretion, demonstrating its robustness across various initial conditions.

Findings

MHD winds can reproduce the observed Md-Macc correlation slope.

The correlation depends on initial conditions and their spread.

Analytical formulas describe the correlation's behavior under different initial scenarios.

Abstract

There is still much uncertainty around the mechanism that rules the accretion of proto-planetary disks. In the last years, Magnetohydrondynamic (MHD) wind-driven accretion has been proposed as a valid alternative to the more conventional viscous accretion. In particular, winds have been shown to reproduce the observed correlation between the mass of the disk Md and the mass accretion rate onto the central star Macc, but this has been done only for specific conditions. It is not clear whether this implies fine tuning or if it is a general result. We investigate under which conditions the observed correlation between the mass of the disk Md and the mass accretion rate onto the central star Macc can be obtained. We find that, in the absence of a correlation between the initial mass M0 and the initial accretion timescale tacc,0, the slope of the Md-Macc correlation depends on the value of the spread of the initial conditions of masses and lifetimes of disks. Then, we clarify the conditions under which a disk population can be fitted with a single power-law. Moreover, we derive an analytical expression for the spread of log(Md/Macc) valid when the spread of tacc is taken to be constant. In the presence of a correlation between M0 and tacc,0, we derive an analytical expression for the slope of the Md-Macc correlation in the initial conditions of disks and at late times. We conclude that MHD winds can predict the observed values of the slope and the spread of the Md-Macc correlation under a broad range of initial conditions. This is a fundamental expansion of previous works on the MHD paradigm, exploring the establishment of this fundamental correlation beyond specific initial conditions.