Matter-Wave Fields for Double-Slit Atom Interferometry: Variational Versus Exact Solitons

TL;DR

This paper compares variational and exact soliton solutions of the Gross-Pitaevskii equation to model matter-wave fields in double-slit atom interferometry, highlighting the superiority of the exact solution for coherent field description.

Contribution

It demonstrates that the exact soliton solution better describes matter-wave fields in double-slit interferometry than common variational approximations.

Findings

Exact solutions align more closely with numerical simulations.

Variational wavefunctions like Hermite-Gaussian are less accurate.

Exact solutions effectively model the generation and evolution of matter-wave fields.

Abstract

A major challenge in the theoretical modeling of double-slit interferometry involving matter-wave fields is the appropriate waveform to be assigned to this field. While all the studies carried out to date on this issue deal with variational fields, experiments suggest that the optical field is generated by splitting a single-hump Bose-Einstein condensate into two spatially and temporally entangled pulses indicating the possibility of fully controlling the subsequent motion of the two output pulses. To probe the consistency of variational and exact soliton solutions to the field equation, we solve the Gross-Pitaevskii equation with an optical potential barrier assumed to act as a beam splitter, while including gravity. The exact solution is compared with the two most common variational wavefunctions, namely, the Hermite-Gaussian and super-sech modes. From numerical simulations, evidence is given of the exact solution as being the most appropriate matter-wave structure that provides a coherent description of the generation and spatio-temporal evolution of matter-wave optical fields in a hypothetical implementation of double-slit atom interferometry