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Main Author: Kopeikin, Sergei M.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2505.14712
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author Kopeikin, Sergei M.
author_facet Kopeikin, Sergei M.
contents We present a rigorous framework for determining equilibrium configurations of uniformly rotating self-gravitating fluid bodies. This work addresses the longstanding challenge of modeling rotational deformation in celestial objects such as stars and planets. By integrating classical Newtonian potential theory with modern mathematical tools, we develop a unified formalism that improves both the precision and generality of shape modeling in astrophysical contexts. Our method employs Lie group theory and exponential mapping to characterize vector flows associated with rotational deformations. We derive functional equations for perturbations in density and gravitational potential, resolved analytically using the shift operator and Neumann series. This extends Clairaut's classical linear theory into the nonlinear regime. The resulting formulation yields an exact nonlinear differential equation for the shape function, describing hydrostatic equilibrium under rotation without assuming slow rotation. This generalized Clairaut equation incorporates nonlinear effects and accommodates large rotational speeds. We validate the theory by deriving exact solutions, including the Maclaurin spheroid, Jacobi ellipsoid, and the unit-index polytrope. We also introduce spectral decomposition techniques to analyze radial harmonics of the shape function and gravitational perturbations. Using Wigner's formalism for angular momentum addition, we compute higher-order spectral corrections and derive boundary conditions for radial harmonics. This enables accurate computation of Love numbers and gravitational multipole moments, offering a comprehensive, non-perturbative approach to modeling rotational deformations in astrophysical systems.
format Preprint
id arxiv_https___arxiv_org_abs_2505_14712
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Lie Group Theory of Multipole Moments and Shape of Stationary Rotating Fluid Bodies
Kopeikin, Sergei M.
Classical Physics
Earth and Planetary Astrophysics
Solar and Stellar Astrophysics
General Relativity and Quantum Cosmology
Mathematical Physics
Fluid Dynamics
Geophysics
76M60 76M60 76M60 (Primary) 35G20, 35J60, 39B22, 76U05, 76U99 (Secondary)
We present a rigorous framework for determining equilibrium configurations of uniformly rotating self-gravitating fluid bodies. This work addresses the longstanding challenge of modeling rotational deformation in celestial objects such as stars and planets. By integrating classical Newtonian potential theory with modern mathematical tools, we develop a unified formalism that improves both the precision and generality of shape modeling in astrophysical contexts. Our method employs Lie group theory and exponential mapping to characterize vector flows associated with rotational deformations. We derive functional equations for perturbations in density and gravitational potential, resolved analytically using the shift operator and Neumann series. This extends Clairaut's classical linear theory into the nonlinear regime. The resulting formulation yields an exact nonlinear differential equation for the shape function, describing hydrostatic equilibrium under rotation without assuming slow rotation. This generalized Clairaut equation incorporates nonlinear effects and accommodates large rotational speeds. We validate the theory by deriving exact solutions, including the Maclaurin spheroid, Jacobi ellipsoid, and the unit-index polytrope. We also introduce spectral decomposition techniques to analyze radial harmonics of the shape function and gravitational perturbations. Using Wigner's formalism for angular momentum addition, we compute higher-order spectral corrections and derive boundary conditions for radial harmonics. This enables accurate computation of Love numbers and gravitational multipole moments, offering a comprehensive, non-perturbative approach to modeling rotational deformations in astrophysical systems.
title Lie Group Theory of Multipole Moments and Shape of Stationary Rotating Fluid Bodies
topic Classical Physics
Earth and Planetary Astrophysics
Solar and Stellar Astrophysics
General Relativity and Quantum Cosmology
Mathematical Physics
Fluid Dynamics
Geophysics
76M60 76M60 76M60 (Primary) 35G20, 35J60, 39B22, 76U05, 76U99 (Secondary)
url https://arxiv.org/abs/2505.14712