Phase Space Quantum Mechanics

TL;DR

This paper develops phase space quantum mechanics as a deformation of classical mechanics, introducing a noncommutative star-product and a space of states, showing its fundamental nature and equivalence to traditional quantum mechanics.

Contribution

It presents a comprehensive formalism of phase space quantum mechanics based on deformation quantization, establishing its fundamental status and equivalence to standard quantum mechanics.

Findings

Deformation of classical mechanics via star-products and Poisson brackets.

Introduction of a space of states with pseudo-probability distributions.

Proof of the formalism's fundamental nature and equivalence to traditional quantum mechanics.

Abstract

The paper develop the alternative formulation of quantum mechanics known as the phase space quantum mechanics or deformation quantization. It is shown that the quantization naturally arises as an appropriate deformation of the classical Hamiltonian mechanics. More precisely, the deformation of the point-wise product of observables to an appropriate noncommutative $\star$-product and the deformation of the Poisson bracket to an appropriate Lie bracket is the key element in introducing the quantization of classical Hamiltonian systems. The considered class of deformations and the corresponding $\star$-products contains as a special cases all deformations which can be found in the literature devoted to the subject of the phase space quantum mechanics. Fundamental properties of $\star$-products of observables, associated with the considered deformations are presented as well. Moreover, a space of states containing all admissible states is introduced, where the admissible states are appropriate pseudo-probability distributions defined on the phase space. It is proved that the space of states is endowed with a structure of a Hilbert algebra with respect to the $\star$-multiplication. The most important result of the paper shows that developed formalism is more fundamental then the axiomatic ordinary quantum mechanics which appears in the presented approach as the intrinsic element of the general formalism. The equivalence of two formulations of quantum mechanics is proved by observing that the Wigner-Moyal transform has all properties of the tensor product. This observation allows writing many previous results found in the literature in a transparent way, from which the equivalence of the two formulations of quantum mechanics follows naturally.