Seismic Sounding of Convection in the Sun

Thermal convection is the dominant mechanism of energy transport in the outer envelope of the Sun (one-third by radius). It drives global fluid circulations and magnetic fields observed on the solar surface. Vigorous surface convection excites a broadband spectrum of acoustic waves that propagate wi...

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Bibliographic Details
Published in:Annual review of fluid mechanics 2016-01, Vol.48 (1), p.191-217
Main Authors: Hanasoge, Shravan, Gizon, Laurent, Sreenivasan, Katepalli R
Format: Article
Language:English
Subjects:
Acoustics
Computer simulation
Convection
Differential rotation
heat transport
helioseismology
Mathematical models
non-Boussinesq effects
Seismic waves
Sounding
Sun
turbulent convection
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Summary:Thermal convection is the dominant mechanism of energy transport in the outer envelope of the Sun (one-third by radius). It drives global fluid circulations and magnetic fields observed on the solar surface. Vigorous surface convection excites a broadband spectrum of acoustic waves that propagate within the interior and set up modal resonances. These acoustic waves, also called seismic waves in this context, are observed at the surface of the Sun by space- and ground-based telescopes. Seismic sounding, the study of these seismic waves to infer the internal properties of the Sun, constitutes helioseismology. Here we review our knowledge of solar convection, especially that obtained through seismic inference. Several characteristics of solar convection, such as differential rotation, anisotropic Reynolds stresses, the influence of rotation on convection, and supergranulation, are considered. On larger scales, several inferences suggest that convective velocities are substantially smaller than those predicted by theory and simulations. This discrepancy challenges the models of internal differential rotation that rely on convective stresses as a driving mechanism and provide an important benchmark for numerical simulations.
ISSN:0066-4189
1545-4479
DOI:10.1146/annurev-fluid-122414-034534