The Noncommutative Poisson Algebra of Classical and Quantum Mechanics

TL;DR

This paper explores a unified algebraic framework for classical and quantum mechanics using noncommutative Poisson algebras derived from Lie-Rinehart structures, revealing geometric origins of quantization.

Contribution

It introduces a noncommutative Poisson algebra structure that unifies classical and quantum mechanics through a common geometric algebraic framework.

Findings

Classical and quantum mechanics are realized as specific cases of a noncommutative Poisson algebra.

Quantization emerges naturally from the algebraic structure as a central variable Z.

Representations of the algebra correspond to classical or quantum states depending on Z.

Abstract

The Lie-Rinehart algebra of a manifold M, defined by the Lie structure of the vector fields, their action and their module structure on the infinitely differentiable functions on M, is a common, diffeomorphism invariant, algebra for both classical and quantum mechanics. Its (noncommutative) Poisson universal enveloping algebra contains a central variable Z which relates the commutators to the Lie products; classical and quantum mechanics are its only factorial realizations, corresponding to the indentification of Z with i times the Planck constant. In this form, canonical quantization appears therefore as a consequence of such a general geometrical structure. The regular factorial Hilbert space representations are, for nonzero values of Z, unitarily equivalent, apart from multiplicity, to one of the irreducible quantum representations, which are locally Schroedinger and in one to one correspondence with the unitary irreducible representations of the fundamental group of M. For Z = 0, if Diff(M) is unitarily implemented, they are unitarily equivalent, up to multiplicity, to the representation defined by classical mechanics on M.