Path integrals and the double slit

TL;DR

This paper offers a path integral approach to understanding matter wave diffraction through a double slit, clarifying phase differences and addressing limitations of the matter-optics analogy for better conceptual explanations.

Contribution

It introduces a path integral framework for matter waves in double slit diffraction, highlighting differences from optical waves and providing a thought experiment to validate phase approximations.

Findings

Path integral description clarifies matter wave interference.

Phase difference approximation is valid within certain conditions.

Highlights limitations of matter-optics analogy in diffraction.

Abstract

Basic explanations of the double slit diffraction phenomenon include a description of waves that emanate from two slits and interfere. The locations of the interference minima and maxima are determined by the phase difference of the waves. An optical wave, which has a wavelength ${\lambda}$ and propagates a distance $L$, accumulates a phase of $2{\pi}L{/}{\lambda}$. A matter wave, also having wavelength ${\lambda}$ and propagating the same distance $L$, accumulates a phase of ${\pi}L{/}{\lambda}$, which is a factor of two different from the optical case. Nevertheless, the phase difference, ${\Delta}{\phi}$, for interfering matter waves that propagate distances that differ by ${\Delta}L$, is approximately $2{\pi}{\Delta}L{/}{\lambda}$, which is the same value computed in the optical case. The difference between the matter and optical case hinders conceptual explanations of diffraction from two slits based on the matter-optics analogy. In the following article we provide a path integral description for matter waves with a focus on conceptual explanation. A thought experiment is provided to illustrate the validity range of the approximation ${\Delta}{\phi}{\approx}2{\pi}{\Delta}L{/}{\lambda}$.