Tearing Instability and Current-Sheet Disruption in the Turbulent Dynamo

Turbulence in a conducting plasma can amplify seed magnetic fields in what is known as the turbulent, or small-scale, dynamo. The associated growth rate and emergent magnetic-field geometry depend sensitively on the material properties of the plasma, in particular on the Reynolds number Re, the magn...

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Bibliographic Details
Published in:Physical review. X 2022-12, Vol.12 (4), p.041027, Article 041027
Main Authors: Galishnikova, Alisa K., Kunz, Matthew W., Schekochihin, Alexander A.
Format: Article
Language:English
Subjects:
Amplification
Coherence
Conducting fluids
Disruption
Dissipation
Electrical resistivity
Energy spectra
Fluid flow
Galactic clusters
High resolution
Magnetic fields
Magnetic properties
Magnetism
Magnetohydrodynamic simulation
Magnetohydrodynamic turbulence
Material properties
Plasma
Plasma turbulence
Reynolds number
Simulation
Tearing
Turbulent flow
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Summary:Turbulence in a conducting plasma can amplify seed magnetic fields in what is known as the turbulent, or small-scale, dynamo. The associated growth rate and emergent magnetic-field geometry depend sensitively on the material properties of the plasma, in particular on the Reynolds number Re, the magnetic Reynolds number Rm, and their ratioPm≡Rm/Re. ForPm>1 , the amplified magnetic field is gradually arranged into a folded structure, with direction reversals at the resistive scale and field lines curved at the larger scale of the flow. As the mean magnetic energy grows to come into approximate equipartition with the fluid motions, this folded structure is thought to persist. Using analytical theory and high-resolution-magnetohydrodynamics simulations with the athena++ code, we show that these magnetic folds become unstable to tearing during the nonlinear stage of the dynamo forRm≳104andRe≳103. An Rm- and Pm-dependent tearing scale, at and below which folds are disrupted, is predicted theoretically and found to match well the characteristic field-reversal scale measured in the simulations. The disruption of folds by tearing increases the ratio of viscous-to-resistive dissipation. In the saturated state, the magnetic-energy spectrum exhibits a sub-tearing-scale steepening to a slope consistent with that predicted for tearing-mediated Alfvénic turbulence. Its spectral peak appears to be independent of the resistive scale and comparable to the driving scale of the flow, while the magnetic energy resides in a broad range of scales extending down to the field-reversal scale set by tearing. Emergence of a degree of large-scale magnetic coherence in the saturated state of the turbulent dynamo may be consistent with observations of magnetic-field fluctuations in galaxy clusters and recent laboratory experiments.
ISSN:2160-3308
2160-3308
DOI:10.1103/PhysRevX.12.041027