Impact of convection and resistivity on angular momentum transport in dwarf novae

TL;DR

This study uses MHD simulations to explore how convection and resistivity influence angular momentum transport in dwarf novae disks, revealing complex relationships and challenges in explaining quiescent accretion.

Contribution

It demonstrates the impact of convection on turbulence and highlights the quenching of MRI-driven transport due to resistivity in cold, weakly ionized disks.

Findings

High alpha values (~0.1) occur near the hot branch tip with active convection.

Resistivity suppresses MRI turbulence below a critical density, halting accretion in quiescence.

Convection does not have a straightforward correlation with alpha values.

Abstract

The eruptive cycles of dwarf novae (DN) are thought to be due to a thermal-viscous instability in the accretion disk surrounding the white dwarf (WD). This model has long been known to imply a stress to pressure ratio \alpha ~0.1 in outburst compared to \alpha ~ 0.01 in quiescence. Such an enhancement in $\alpha$ has recently been observed in simulations of turbulent transport driven by the magneto-rotational instability (MRI) when convection is present, without requiring a net magnetic flux. We independently recover this result by carrying out PLUTO MHD simulations of vertically stratified, radiative, shearing boxes with the thermodynamics and opacities appropriate to DN. The results are robust against the choice of vertical boundary conditions. The thermal equilibrium solutions found by the simulations trace the well-known S-curve in the density-temperature plane. We confirm that the high values of \alpha ~ 0.1 occur near the tip of the hot branch of the S-curve, where convection is active. However, we also present thermally-stable simulations at lower temperatures that have standard values of \alpha ~ 0.03 despite the presence of vigorous convection. We find no simple relationship between \alpha and the strength of the convection, as measured by the ratio of convective to radiative flux. The cold branch is only very weakly ionized so, in the second part of this work, we studied the impact of non-ideal MHD effects on transport. We include resistivity in the simulations and find that the MRI-driven transport is quenched (\alpha ~ 0) below the critical density at which the magnetic Reynolds number R_m \leq 10^4. This is problematic as X-ray emission observed in quiescent systems requires ongoing accretion onto the WD. We verify that these X-rays cannot self-sustain MRI-driven turbulence by photo-ionizing the disk and discuss possible solutions to the issue of accretion in quiescence.