Accretion Disks and Dynamos: Toward a Unified Mean Field Theory

TL;DR

This paper explores the potential for a unified mean field theory that connects accretion disk physics and magnetic dynamo processes, emphasizing the role of magnetic helicity fluxes and nonlinear effects.

Contribution

It discusses progress towards integrating accretion and dynamo theories, highlighting the importance of magnetic helicity fluxes and nonlinear dynamics in a unified framework.

Findings

Large scale magnetic fields can be sustained without kinetic helicity.

Helicity fluxes and small scale fluctuations are crucial for dynamo action.

Disk hemispheres should be studied separately to avoid misleading cancellations.

Abstract

Conversion of gravitational energy into radiation in accretion discs and the origin of large scale magnetic fields in astrophysical rotators have often been distinct topics of research. In semi-analytic work on both problems it has been useful to presume large scale symmetries, necessarily resulting in mean field theories. MHD turbulence makes the underlying systems locally asymmetric and nonlinear. Synergy between theory and simulations should aim for the development of practical mean field models that capture essential physics and can be used for observational modeling. Mean field dynamo (MFD) theory and alpha-viscosity accretion theory exemplify such ongoing pursuits. 21st century MFD theory has more nonlinear predictive power compared to 20th century MFD theory, whereas accretion theory is still in a 20th century state. In fact, insights from MFD theory are applicable to accretion theory and the two are artificially separated pieces of what should be a single theory. I discuss pieces of progress that provide clues toward a unified theory. A key concept is that large scale magnetic fields can be sustained via local or global magnetic helicity fluxes or via relaxation of small scale magnetic fluctuations, without the kinetic helicity driver of 20th century textbooks. These concepts may help explain the formation of large scale fields that supply non-local angular momentum transport via coronae and jets in a unified theory of accretion and dynamos. In diagnosing the role of helicities and helicity fluxes in disk simulations, each disk hemisphere should be studied separately to avoid being misled by cancelation that occurs as a result of reflection asymmetry. The fraction of helical field energy in disks is expected to be small compared to the total field in each hemisphere as a result of shear, but can still be essential for large scale dynamo action.