Decoherence effects in Bose-Einstein condensate interferometry. I General Theory

TL;DR

This paper develops a comprehensive theoretical framework for analyzing decoherence and dephasing in Bose-Einstein condensate interferometry, employing phase space distribution methods and stochastic equations to interpret experimental results.

Contribution

It introduces a hybrid phase space approach combining Wigner and positive P representations for modeling BEC interferometry with decoherence effects.

Findings

Derived a functional Fokker-Planck equation for the system

Formulated Ito stochastic equations for condensate and non-condensate fields

Provided a method to compute quantum correlation functions from stochastic averages

Abstract

The present paper outlines a basic theoretical treatment of decoherence and dephasing effects in interferometry based on single component BEC in double potential wells, where two condensate modes may be involved. Results for both two mode condensates and the simpler single mode condensate case are presented. A hybrid phase space distribution functional method is used where the condensate modes are described via a truncated Wigner representation, and the basically unoccupied non-condensate modes are described via a positive P representation. The Hamiltonian for the system is described in terms of quantum field operators for the condensate and non-condensate modes. The functional Fokker-Planck equation for the double phase space distribution functional is derived. Equivalent Ito stochastic equations for the condensate and non-condensate fields that replace the field operators are obtained, and stochastic averages of products of these fields give the quantum correlation functions used to interpret interferometry experiments. The stochastic field equations are the sum of a deterministic term obtained from the drift vector in the functional Fokker-Planck equation, and a noise field whose stochastic properties are determined from the diffusion matrix in the functional Fokker-Planck equation. The noise field stochastic properties are similar to those for Gaussian-Markov processes in that the stochastic averages of odd numbers of noise fields are zero and those for even numbers of noise field terms are sums of products of stochastic averages associated with pairs of noise fields. However each pair is represented by an element of the diffusion matrix rather than products of the noise fields themselves. The treatment starts from a generalised mean field theory for two condensate mode. The generalized mean field theory solutions are needed for calculations using the Ito stochastic field equations.