Saved in:
Bibliographic Details
Main Authors: Crowe, Matthew. N., Sutyrin, Georgi. G.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2410.14402
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866917855257165824
author Crowe, Matthew. N.
Sutyrin, Georgi. G.
author_facet Crowe, Matthew. N.
Sutyrin, Georgi. G.
contents We study the evolution of eastward propagating dipoles (modons) in a two-layer quasi-geostrophic $β$-plane model using high-resolution numerical simulations. Various combinations of background gradients of potential vorticity in the upper and lower layer (which may include sloping topography) shed light on the recently discovered breakdown mechanisms and rich dynamics of dipolar vortices. Owing to the $β$-effect in the upper layer with active dipolar vortices, the symmetry of the dipole flow breaks due to an exponentially-growing, rotating, asymmetric mode of linear instability associated with Rossby wave radiation. Further nonlinear transformation is found to consist of two phases: fast partner separation, resulting in a deceleration of the eastward drift, and subsequent slow separation with a saturated asymmetric mode accompanied by much weaker, shorter Rossby waves. This weakly radiating phase -- with pulsating partners and homogenized potential vorticity between the core and the separatrix -- can be considered as a new type of long-lived dipole. Conversely, when no $β$-effect is present in the upper layer, the dipoles remain nearly symmetric, even when the topographic $β$-effect is present in the active lower layer. In this case, the development of a weak asymmetric mode is related to a small meridional shift of the dipole center on the numerical grid.
format Preprint
id arxiv_https___arxiv_org_abs_2410_14402
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Symmetry breaking and nonlinear transformation of two-layer eastward propagating dipoles
Crowe, Matthew. N.
Sutyrin, Georgi. G.
Fluid Dynamics
We study the evolution of eastward propagating dipoles (modons) in a two-layer quasi-geostrophic $β$-plane model using high-resolution numerical simulations. Various combinations of background gradients of potential vorticity in the upper and lower layer (which may include sloping topography) shed light on the recently discovered breakdown mechanisms and rich dynamics of dipolar vortices. Owing to the $β$-effect in the upper layer with active dipolar vortices, the symmetry of the dipole flow breaks due to an exponentially-growing, rotating, asymmetric mode of linear instability associated with Rossby wave radiation. Further nonlinear transformation is found to consist of two phases: fast partner separation, resulting in a deceleration of the eastward drift, and subsequent slow separation with a saturated asymmetric mode accompanied by much weaker, shorter Rossby waves. This weakly radiating phase -- with pulsating partners and homogenized potential vorticity between the core and the separatrix -- can be considered as a new type of long-lived dipole. Conversely, when no $β$-effect is present in the upper layer, the dipoles remain nearly symmetric, even when the topographic $β$-effect is present in the active lower layer. In this case, the development of a weak asymmetric mode is related to a small meridional shift of the dipole center on the numerical grid.
title Symmetry breaking and nonlinear transformation of two-layer eastward propagating dipoles
topic Fluid Dynamics
url https://arxiv.org/abs/2410.14402