Simulation of Quantum Spin Dynamics by Phase Space Sampling of BBGKY Trajectories

TL;DR

This paper introduces a numerical simulation method for quantum spin dynamics that combines phase space sampling with BBGKY hierarchy evolution, enabling accurate modeling of long-range interactions in arbitrary lattice dimensions.

Contribution

The paper presents a novel approach integrating Wigner function sampling with BBGKY hierarchy equations for systematic and accurate quantum spin dynamics simulation.

Findings

Accurately reproduces exact results for quantum spin models.

Effective for long-range interacting systems.

Predicts spin squeezing in 2D lattices with power-law interactions.

Abstract

A numerical method, suitable for the simulation of the time evolution of quantum spin models of arbitrary lattice dimension, is presented. The method combines sampling of the Wigner function with evolution equations obtained from the Bogoliubov-Born-Green-Kirkwood-Yvon (BBGKY) hierarchy. Going to higher orders of the BBGKY hierarchy allows for a systematic refinement of the method. Quantum correlations are treated through both, the Wigner function sampling and the BBGKY evolution, bringing about highly accurate estimates of correlation functions. The method is particularly suitable for long-range interacting systems, and we demonstrate its power by comparing with exact results as well as other numerical methods. As an application we compute spin squeezing in a two-dimensional lattice with power-law interactions and a transverse field, which should be accessible in future ion trap experiments.