Discrete Phase Space: Quantum mechanics and non-singular potential functions

TL;DR

This paper explores various potential equations in quantum mechanics across different spaces, demonstrating that a discrete phase space representation yields a non-singular, invariant potential that exactly reproduces quantum mechanics.

Contribution

It introduces an exact discrete phase space representation of quantum mechanics with a non-singular, invariant potential, contrasting with traditional singular and non-invariant potentials.

Findings

Discrete phase space potential is non-singular and invariant.

The discrete phase space representation exactly reproduces quantum mechanics.

Comparison of potentials across Euclidean, lattice, and phase space scenarios.

Abstract

The three-dimensional potential equation, motivated by representations of quantum mechanics, is investigated in four different scenarios: (i) In the usual Euclidean space $\mathbb{E}_{3}$ where the potential is singular but invariant under the continuous inhomogeneous orthogonal group $\mathcal{I}O(3)$. The invariance under the translation subgroup is compared to the corresponding unitary transformation in the Schr\"{o}dinger representation of quantum mechanics. This scenario is well known but serves as a reference point for the other scenarios. (ii) Next, the discrete potential equation as a partial difference equation in a three-dimensional lattice space is studied. In this arena the potential is non-singular but invariance under $\mathcal{I}O(3)$ is broken. This is the usual picture of lattice theories and numerical approximations. (iii) Next we study the six-dimensional continuous phase space. Here a phase space representation of quantum mechanics is utilized. The resulting potential is singular but possesses invariance under $\mathcal{I}O(3)$. (iv) Finally, the potential is derived from the discrete phase space representation of quantum mechanics, which is shown to be an \emph{exact} representation of quantum mechanics. The potential function here is both non-singular and possesses invariance under $\mathcal{I}O(3)$, and this is proved via the unitary transformations of quantum mechanics in this representation.