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Bibliographic Details
Main Authors: Lichtenfelz, Leandro, Modin, Klas, Preston, Stephen C.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.09833
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author Lichtenfelz, Leandro
Modin, Klas
Preston, Stephen C.
author_facet Lichtenfelz, Leandro
Modin, Klas
Preston, Stephen C.
contents The geometric description of incompressible hydrodynamics, as geodesic motion on the infinite-dimensional group of volume-preserving diffeomorphisms, enables notions of curvature in the study of fluids in order to study stability. Formulas for Ricci curvature are often simpler than those for sectional curvature, which typically takes both signs, but the drawback is that Ricci curvature is rarely well-defined in infinite-dimensional spaces. Here we suggest a definition of Ricci curvature in the case of two-dimensional hydrodynamics, based on the finite-dimensional Zeitlin models arising in quantization theory, which gives a natural tool for renormalization. We provide formulae for the finite-dimensional approximations and give strong numerical evidence that these converge in the infinite-dimensional limit, based in part on four new conjectured identities for Wigner $6j$ symbols. The suggested limiting expression for (average) Ricci curvature is surprisingly simple and demonstrates an average instability for high-frequency modes which helps explain long-term numerical observations of spherical hydrodynamics due to mixing.
format Preprint
id arxiv_https___arxiv_org_abs_2508_09833
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Ricci curvature for hydrodynamics on the sphere
Lichtenfelz, Leandro
Modin, Klas
Preston, Stephen C.
Differential Geometry
35Q31, 53C21, 37K25, 81S10
The geometric description of incompressible hydrodynamics, as geodesic motion on the infinite-dimensional group of volume-preserving diffeomorphisms, enables notions of curvature in the study of fluids in order to study stability. Formulas for Ricci curvature are often simpler than those for sectional curvature, which typically takes both signs, but the drawback is that Ricci curvature is rarely well-defined in infinite-dimensional spaces. Here we suggest a definition of Ricci curvature in the case of two-dimensional hydrodynamics, based on the finite-dimensional Zeitlin models arising in quantization theory, which gives a natural tool for renormalization. We provide formulae for the finite-dimensional approximations and give strong numerical evidence that these converge in the infinite-dimensional limit, based in part on four new conjectured identities for Wigner $6j$ symbols. The suggested limiting expression for (average) Ricci curvature is surprisingly simple and demonstrates an average instability for high-frequency modes which helps explain long-term numerical observations of spherical hydrodynamics due to mixing.
title Ricci curvature for hydrodynamics on the sphere
topic Differential Geometry
35Q31, 53C21, 37K25, 81S10
url https://arxiv.org/abs/2508.09833