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On the saturation mechanism of the fluctuation dynamo at {Pr_M} ge 1

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arxiv 2003.07997 v1 pith:LQYXR2LM submitted 2020-03-18 astro-ph.GA physics.flu-dynphysics.plasm-ph

On the saturation mechanism of the fluctuation dynamo at {Pr_M} ge 1

classification astro-ph.GA physics.flu-dynphysics.plasm-ph
keywords magneticdynamofieldamplificationfluctuationstructuresdiffusionenergy
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The presence of magnetic fields in many astrophysical objects is due to dynamo action, whereby a part of the kinetic energy is converted into magnetic energy. A turbulent dynamo that produces magnetic field structures on the same scale as the turbulent flow is known as the fluctuation dynamo. We use numerical simulations to explore the nonlinear, statistically steady state of the fluctuation dynamo in driven turbulence. We demonstrate that as the magnetic field growth saturates, its amplification and diffusion are both affected by the back-reaction of the Lorentz force upon the flow. The amplification of the magnetic field is reduced due to stronger alignment between the velocity field, magnetic field, and electric current density. Furthermore, we confirm that the amplification decreases due to a weaker stretching of the magnetic field lines. The enhancement in diffusion relative to the field line stretching is quantified by a decrease in the computed local value of the magnetic Reynolds number. Using the Minkowski functionals, we quantify the shape of the magnetic structures produced by the dynamo as magnetic filaments and ribbons in both kinematic and saturated dynamos and derive the scalings of the typical length, width, and thickness of the magnetic structures with the magnetic Reynolds number. We show that all three of these magnetic length scales increase as the dynamo saturates. The magnetic intermittency, strong in the kinematic dynamo (where the magnetic field strength grows exponentially) persists in the statistically steady state, but intense magnetic filaments and ribbons are more volume-filling.

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Cited by 4 Pith papers

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