Model spaces as constrained Hamiltonian systems: I. Application to $\mathrm{SU}(2)$

TL;DR

This paper explores the quantization of model spaces for Lie groups using constrained Hamiltonian systems, focusing on the SU(2) case to connect with angular momentum and spherical harmonics.

Contribution

It introduces a unified Hamiltonian framework for constructing and quantizing model spaces for Lie groups, exemplified by the SU(2) case, linking to angular momentum theory.

Findings

Recovered known quantum angular momentum results

Provided insights into spin-weighted and monopole spherical harmonics

Clarified the structure of symplectic submanifolds in $T^*G$

Abstract

Motivated by group-theoretical questions that arise in the context of asymptotic symmetries in gravity, we study model spaces and their quantization from the viewpoint of constrained Hamiltonian systems. More precisely, we propose that a central building block in the construction of the model space for a generic Lie group $G$ is the symplectic submanifold of $T^*G$ that one obtains when one imposes only the second class constraints in the construction of the coadjoint orbit as a symplectic quotient. Before turning to the non-compact infinite-dimensional groups relevant in the gravitational setting, we work out all details in the simplest case of $\mathrm{SU}(2)$. Besides recovering well-known results on the quantum theory of angular momentum from a unified perspective, the analysis sheds some light on the definition and properties of spin-weighted/monopole spherical harmonics.