Abstract
Context.Results from global magnetoconvection simulations of solar-like stars are at odds with observations in many respects: simulations show a surplus of energy in the kinetic power spectrum at large scales; anti-solar differential rotation profiles with accelerated poles, and a slow equator for the solar rotation rate; and a transition from axi- to nonaxisymmetric dynamos at a much lower rotation rate than what is observed. Even though the simulations reproduce the observed active longitudes in fast rotators, their motion in the rotational frame (the so-called azimuthal dynamo wave, ADW) is retrograde, in contrast to the prevalent prograde motion in observations.Aims.We study the effect of a more realistic treatment of heat conductivity in alleviating the discrepancies between observations and simulations.Methods.We use physically motivated heat conduction by applying Kramers opacity law to a semi-global spherical setup that describes the convective envelopes of solar-like stars, instead of a prescribed heat conduction profile from mixing-length arguments.Results.We find that some aspects of the results now better correspond to observations: the axi- to nonaxisymmetric transition point is shifted towards higher rotation rates. We also find a change in the propagation direction of ADWs that means that prograde waves are also now found. However, the transition from an anti-solar to solar-like rotation profile is also shifted towards higher rotation rates, leaving the models in an even more unrealistic regime.Conclusions.Although Kramers-based heat conduction does not help in reproducing the solar rotation profile, it does help in the faster rotation regime, where the dynamo solutions now better match the observations.
Highlights
The solar surface differential rotation has been known for a long time (Scheiner 1630; Carrington 1863): the equator completes a turn in around 25 days, while the poles take roughly 30 days
Results from global magnetoconvection simulations of solar-like stars are at odds with observations in many respects: simulations show a surplus of energy in the kinetic power spectrum at large scales; anti-solar differential rotation profiles with accelerated poles, and a slow equator for the solar rotation rate; and a transition from axi- to nonaxisymmetric dynamos at a much lower rotation rate than what is observed
This paper presents the results of our study of the effect of a dynamically adapting heat-conduction prescription, based on Kramers opacity law, in conjunction with semi-global MHD simulations
Summary
The solar surface differential rotation has been known for a long time (Scheiner 1630; Carrington 1863): the equator completes a turn in around 25 days, while the poles take roughly 30 days. The Sun is able to break the Taylor–Proudman balance by some means Another surprising observational result came from time-distance helioseismology (Hanasoge et al 2012), which revealed a lack of power in the kinetic energy spectrum at large scales, where the peak for giant cells should be located. Such a peak would be expected from mixing-length theory (MLT; Vitense 1953; Böhm-Vitense 1958): in its original formulation, MLT predicts convection at all possible scales, which would correspond to cells of the diameter of the entire convective layer. More recent measurements (e.g., Rincon et al 2017) suggest that supergranulation may be the largest scale excited in the Sun
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