Mean-field concept and direct numerical simulations of rotating magnetoconvection and the geodynamo

Schrinner, M.; Rädler, K.-H.; Schmitt, D.; Rheinhardt, M.; Christensen, Ulrich R.

doi:10.1080/03091920701345707

Cited by 202 publications

(241 citation statements)

References 53 publications

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“…However, in the case of Euler potentials it is not clear what happens and whether this method can be used to simulate even the ideal MHD equations, given that each numerical scheme will introduce some type of diffusion. In this short review, we have also attempted to clarify why numerical calculations of α effect and turbulent diffusion using the standard test-field method (Schrinner et al, 2007) would yield values that can only reproduce a correct growth rate in the case of vanishing growth. In all other case, a representation in terms of integral kernels has to be used.…”

Section: Discussionmentioning

confidence: 99%

“…This provides an important resource for ideas of what one might have been missing in various contexts. Here we just mention the case of the Roberts flow, for which α ij and η ij have been determined using the test-field methods (Schrinner et al, 2007). One might then expect that the growth rate obtained from the underlying dissipation rate, should agree with the value obtained from the direct calculation.…”

Section: Quantitative Comparison Between Simulations and Mean-field Tmentioning

confidence: 99%

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Simulations of astrophysical dynamos

Brandenburg

2010

Proc. IAU

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Abstract. Numerical aspects of dynamos in periodic domains are discussed. Modifications of the solutions by numerically motivated alterations of the equations are being reviewed using the examples of magnetic hyperdiffusion and artificial diffusion when advancing the magnetic field in its Euler potential representation. The importance of using integral kernel formulations in mean-field dynamo theory is emphasized in cases where the dynamo growth rate becomes comparable with the inverse turnover time. Finally, the significance of microscopic magnetic Prandtl number in controlling the conversion from kinetic to magnetic energy is highlighted.

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Section: Discussionmentioning

confidence: 99%

Section: Quantitative Comparison Between Simulations and Mean-field Tmentioning

confidence: 99%

Simulations of astrophysical dynamos

Brandenburg

2010

Proc. IAU

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“…The method was developed by Schrinner et al (2005Schrinner et al ( , 2007 in the context of this task: Consider a simple geodynamo model, with the magnetic field maintained by convection. Define mean fields by averaging over the azimuthal coordinate; they are then axisymmetric.…”

Section: Test-field Methodsmentioning

confidence: 99%

Mean‐field dynamos: The old concept and some recent developments

Rädler

2014

Astron Nachr

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This article elucidates the basic ideas of electrodynamics and magnetohydrodynamics of mean fields in turbulently moving conducting fluids. It is stressed that the connection of the mean electromotive force with the mean magnetic field and its first spatial derivatives is in general neither local nor instantaneous and that quite a few claims concerning pretended failures of the mean-field concept result from ignoring this aspect. In addition to the mean-field dynamo mechanisms of α 2 and αΩ type several others are considered. Much progress in mean-field electrodynamics and magnetohydrodynamics results from the test-field method for calculating the coefficients that determine the connection of the mean electromotive force with the mean magnetic field. As an important example the memory effect in homogeneous isotropic turbulence is explained. In magnetohydrodynamic turbulence there is the possibility of a mean electromotive force that is primarily independent of the mean magnetic field and labeled as Yoshizawa effect. Despite of many efforts there is so far no convincing comprehensive theory of α quenching, that is, the reduction of the α effect with growing mean magnetic field, and of the saturation of mean-field dynamos. Steps toward such a theory are explained. Finally, some remarks on laboratory experiments with dynamos are made.

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“…This method is known as the test-field method and was developed by Schrinner et al (2005Schrinner et al ( , 2007 to calculate all tensor components from snapshots of simulations of the geodynamo in a spherical shell. This method was later applied to time-dependent turbulence in triply-periodic Cartesian domains, both with shear and no helicity (Brandenburg 2005 The test-field method has recently been criticized by Cattaneo & Hughes (2008) on the grounds that the test fields are arbitrary pre-determined mean fields.…”

Section: The Test-field Methodsmentioning

confidence: 99%

Advances in Theory and Simulations of Large-Scale Dynamos

Brandenburg

2009

Space Sci Rev

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Recent analytical and computational advances in the theory of large-scale dynamos are reviewed. The importance of the magnetic helicity constraint is apparent even without invoking mean-field theory. The tau approximation yields expressions that show how the magnetic helicity gets incorporated into mean-field theory. The test-field method allows an accurate numerical determination of turbulent transport coefficients in linear and nonlinear regimes. Finally, some critical views on the solar dynamo are being offered and targets for future research are highlighted.

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Mean-field concept and direct numerical simulations of rotating magnetoconvection and the geodynamo

Cited by 202 publications

References 53 publications

Simulations of astrophysical dynamos

Simulations of astrophysical dynamos

Mean‐field dynamos: The old concept and some recent developments

Advances in Theory and Simulations of Large-Scale Dynamos

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