Scaling Symmetry and Integrable Spherical Hydrostatics

TL;DR

This paper extends Noether's Theorem to non-variational symmetries, providing a new variational formulation for spherical hydrostatics, which helps analyze polytropes, core structures, and solutions like Emden's in astrophysics.

Contribution

It introduces a novel synthesis of group theory, hydrostatics, and astrophysics to analyze scale-invariant systems and polytropes, including defining a core radius and deriving solutions.

Findings

Derived non-conservation laws from non-variational symmetries.

Revealed a common core structure in polytropes of different indices.

Obtained Emden solutions and useful approximations.

Abstract

Any symmetry reduces a second-order differential equation to a first integral: variational symmetries of the action (exemplified by central field dynamics) lead to conservation laws, but symmetries of only the equations of motion (exemplified by scale-invariant hydrostatics) yield first-order {\em non-conservation laws} between invariants. We obtain these non-conservation laws by extending Noether's Theorem to non-variational symmetries and present an innovative variational formulation of spherical adiabatic hydrostatics. For the scale-invariant case, this novel synthesis of group theory, hydrostatics, and astrophysics allows us to recover all the known properties of polytropes and define a {\em core radius}, inside which polytropes of index $n$ share a common core mass density structure, and outside of which their envelopes differ. The Emden solutions (regular solutions of the Lane-Emden equation) are obtained, along with useful approximations. An appendix discusses the $n=3$ polytrope in order to emphasize how the same mechanical structure allows different thermal structures in relativistic degenerate white dwarfs and zero age main sequence stars.