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On large-scale dynamos with stable stratification and the application to stellar radiative zones

Valentin Skoutnev, Jonathan Squire, A. Bhattacharjee

2022Monthly Notices of the Royal Astronomical Society10 citationsDOIOpen Access PDF

Abstract

Abstract Our understanding of large-scale magnetic fields in stellar radiative zones remains fragmented and incomplete. Such magnetic fields, which must be produced by some form of dynamo mechanism, are thought to dominate angular-momentum transport, making them crucial to stellar evolution. A major difficulty is the effect of stable stratification, which generally suppresses dynamo action. We explore the effects of stable stratification on mean-field dynamo theory with a particular focus on a non-helical large-scale dynamo (LSD) mechanism known as the magnetic shear-current effect. We find that the mechanism is robust to increasing stable stratification as long as the original requirements for its operation are met: a source of shear and non-helical magnetic fluctuations (e.g. from a small-scale dynamo). Both are plausibly sourced in the presence of differential rotation. Our idealized direct numerical simulations, supported by mean-field theory, demonstrate the generation of near equipartition large-scale toroidal fields. Additionally, a scan over magnetic Reynolds number shows no change in the growth or saturation of the LSD, providing good numerical evidence of a dynamo mechanism resilient to catastrophic quenching, which has been an issue for helical dynamos. These properties – the absence of catastrophic quenching and robustness to stable stratification – make the mechanism a plausible candidate for generating in situ large-scale magnetic fields in stellar radiative zones.

Topics & Concepts

DynamoPhysicsSolar dynamoDifferential rotationRadiative transferDynamo theoryTachoclineStratification (seeds)Magnetic fieldMagnetohydrodynamicsAstrophysicsConvection zoneMagnetic diffusivityComputational physicsMechanicsQuantum mechanicsGerminationBotanySeed dormancyBiologyDormancySolar and Space Plasma DynamicsAstro and Planetary ScienceGeomagnetism and Paleomagnetism Studies