Path integrals from classical momentum paths

TL;DR

This paper introduces a new classical action R for constructing momentum path integrals, providing a broader framework that simplifies calculations and offers practical advantages in quantum mechanics.

Contribution

It formally constructs momentum path integrals from all classical paths using an alternative action R, expanding the theoretical foundation of path integral formulation.

Findings

Normalized amplitude for free particle derived without Schrödinger equation

Internal spin degree of freedom naturally obtained

Simple harmonic oscillator calculation demonstrates method's effectiveness

Abstract

The path integral formulation of quantum mechanics constructs the propagator by evaluating the action S for all classical paths in coordinate space. A corresponding momentum path integral may also be defined through Fourier transforms in the endpoints. Although these momentum path integrals are especially simple for several special cases, no one has, to my knowledge, ever formally constructed them from all classical paths in momentum space. I show that this is possible because there exists another classical mechanics based on an alternate classical action R. Hamilton's Canonical equations result from a variational principle in both S and R. S uses fixed beginning and ending spatial points while R uses fixed beginning and ending momentum points. This alternative action's classical mechanics also includes a Hamilton-Jacobi equation. I also present some important points concerning the beginning and ending conditions on the action necessary to apply a Canonical transformation. These properties explain the failure of the Canonical transformation in the phase space path integral. It follows that a path integral may be constructed from classical position paths using S in the coordinate representation or from classical momentum paths using R in the momentum representation. Several example calculations are presented that illustrate the simplifications and practical advantages made possible by this broader view of the path integral. In particular, the normalized amplitude for a free particle is found without using the Schrodinger equation, the internal spin degree of freedom is simply and naturally derived, and the simple harmonic oscillator is calculated.