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Main Authors: Kim, Eojin, Farrell, Brian F.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.07669
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author Kim, Eojin
Farrell, Brian F.
author_facet Kim, Eojin
Farrell, Brian F.
contents Zonal jets (ZJ) are prominent coherent structures that spontaneously emerge from the background turbulent state in both stellar and planetary atmospheres. Although formation and maintenance of coherent jets from small scale hydrodynamic turbulence is well-documented, the mechanism underlying this phenomenon remains controversial. The dynamics of the Earth's polar jet and that of the quasi-biennial oscillation of the equatorial stratosphere have been analytically explained using the Statistical State Dynamics (SSD) framework applied to mid-latitude beta-plane and stratified turbulence of the equatorial equatorial,respectively (Farrell & Ioannou 2003). Extension of SSD to the shallow water equations of the equatorial beta-plane provided a corresponding theory for the dynamics of Jovian jets (Farrell & Ioannou 2009). However, the influence of Lorentz forces in the dynamics of a substantial subset of coherent structures observed in both planetary and stellar turbulence motivates the further extension of SSD analysis of coherent structure formation to magnetohydrodynamics (MHD) turbulence. In this work, we apply the SSD framework to shallow water MHD turbulence to study coherent structure dynamics in which both Reynolds and Maxwell stresses are involved. Perturbative and nonlinear equilibria SSD solutions reveal formation and statistical equilibration of zonal jet-toroidal field structure (ZJTFS) with both fixed point and time-dependent oscillation behavior with implications for understanding coherent structure formation in MHD turbulence including steady jets such as the solar super-rotation and time-dependent phenomena such as the 22 year old solar cycle.
format Preprint
id arxiv_https___arxiv_org_abs_2603_07669
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Statistical State Dynamics of Large-Scale Structure Formation in Shallow Water Magnetohydrodynamic Turbulence
Kim, Eojin
Farrell, Brian F.
Fluid Dynamics
Zonal jets (ZJ) are prominent coherent structures that spontaneously emerge from the background turbulent state in both stellar and planetary atmospheres. Although formation and maintenance of coherent jets from small scale hydrodynamic turbulence is well-documented, the mechanism underlying this phenomenon remains controversial. The dynamics of the Earth's polar jet and that of the quasi-biennial oscillation of the equatorial stratosphere have been analytically explained using the Statistical State Dynamics (SSD) framework applied to mid-latitude beta-plane and stratified turbulence of the equatorial equatorial,respectively (Farrell & Ioannou 2003). Extension of SSD to the shallow water equations of the equatorial beta-plane provided a corresponding theory for the dynamics of Jovian jets (Farrell & Ioannou 2009). However, the influence of Lorentz forces in the dynamics of a substantial subset of coherent structures observed in both planetary and stellar turbulence motivates the further extension of SSD analysis of coherent structure formation to magnetohydrodynamics (MHD) turbulence. In this work, we apply the SSD framework to shallow water MHD turbulence to study coherent structure dynamics in which both Reynolds and Maxwell stresses are involved. Perturbative and nonlinear equilibria SSD solutions reveal formation and statistical equilibration of zonal jet-toroidal field structure (ZJTFS) with both fixed point and time-dependent oscillation behavior with implications for understanding coherent structure formation in MHD turbulence including steady jets such as the solar super-rotation and time-dependent phenomena such as the 22 year old solar cycle.
title Statistical State Dynamics of Large-Scale Structure Formation in Shallow Water Magnetohydrodynamic Turbulence
topic Fluid Dynamics
url https://arxiv.org/abs/2603.07669