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Main Authors: Blume, Catherine C., Hindman, Bradley W.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.03832
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author Blume, Catherine C.
Hindman, Bradley W.
author_facet Blume, Catherine C.
Hindman, Bradley W.
contents Though Rossby waves have been observed on the Sun, their radial eigenfunctions remain a mystery. The prior theoretical work either considers quasi-2D systems, which do not apply to the solar interior, or only considers fully radiative or fully convective atmospheres. This project calculates the radial eigenfunctions for Rossby waves in a deep atmosphere for a general stratification. Here, we use the $β$-plane approximation to derive a vertical equation in terms of the Lagrangian pressure fluctuation $δP$, and we then calculate radial eigenfunctions for Rossby waves in a standard solar model, Model S. We find that working in the Lagrangian pressure fluctuation results in cleaner wave equations that lack internal singularities that have been encountered in prior work. The resulting radial wave equation makes it abundantly clear that there are two wave cavities in the solar interior, one in the radiative interior and another in the convection zone. Surprisingly, our calculated radial vorticity eigenfunctions for the radiative interior modes are nearly constant throughout the convection zone, raising the possibility that they may be observable at the solar surface.
format Preprint
id arxiv_https___arxiv_org_abs_2511_03832
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Effects of density stratification on Rossby waves in deep atmospheres
Blume, Catherine C.
Hindman, Bradley W.
Solar and Stellar Astrophysics
Though Rossby waves have been observed on the Sun, their radial eigenfunctions remain a mystery. The prior theoretical work either considers quasi-2D systems, which do not apply to the solar interior, or only considers fully radiative or fully convective atmospheres. This project calculates the radial eigenfunctions for Rossby waves in a deep atmosphere for a general stratification. Here, we use the $β$-plane approximation to derive a vertical equation in terms of the Lagrangian pressure fluctuation $δP$, and we then calculate radial eigenfunctions for Rossby waves in a standard solar model, Model S. We find that working in the Lagrangian pressure fluctuation results in cleaner wave equations that lack internal singularities that have been encountered in prior work. The resulting radial wave equation makes it abundantly clear that there are two wave cavities in the solar interior, one in the radiative interior and another in the convection zone. Surprisingly, our calculated radial vorticity eigenfunctions for the radiative interior modes are nearly constant throughout the convection zone, raising the possibility that they may be observable at the solar surface.
title Effects of density stratification on Rossby waves in deep atmospheres
topic Solar and Stellar Astrophysics
url https://arxiv.org/abs/2511.03832