Correspondence between open bosonic systems and stochastic differential equations

Abstract

Bosonic mean-field theories can approximate the dynamics of systems of n bosons provided that n 1. We show that there can also be an exact correspondence at finite n when the bosonic system is generalized to include interactions with the environment and the mean-field theory is replaced by a stochastic differential equation. When the n ∞ limit is taken, the stochastic terms in this differential equation vanish, and a mean-field theory is recovered. Besides providing insight into the differences between the behavior of finite quantum systems and their classical limits given by n ∞, the developed mathematics can provide a basis for quantum algorithms that solve some stochastic nonlinear differential equations. We discuss conditions on the efficiency of these quantum algorithms, with a focus on the possibility for the complexity to be polynomial in the log of the stochastic system size. A particular system with the form of a stochastic discrete nonlinear Schr\"odinger equation is analyzed in more detail.