One-dimensional Bose gas dynamics: breather relaxation

Bogdan Opanchuk; Peter D. Drummond

arXiv:1708.01013·quant-ph·November 29, 2017

One-dimensional Bose gas dynamics: breather relaxation

Bogdan Opanchuk, Peter D. Drummond

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TL;DR

This paper predicts the relaxation dynamics of quantum breathers in one-dimensional Bose gases with 1000-10,000 particles, using a truncated Wigner approximation, providing testable results for upcoming BEC experiments.

Contribution

It introduces a novel quantum dynamical prediction for breather relaxation in mesoscopic Bose gases using a truncated Wigner approach.

Findings

01

Predicted quantum breather relaxation dynamics for N=10^3-10^4 particles.

02

Validated the truncated Wigner approximation against known predictions.

03

Provided testable predictions for future BEC experiments.

Abstract

One-dimensional Bose gases are a useful testing-ground for quantum dynamics in many-body theory. They allow experimental tests of many-body theory predictions in an exponentially complex quantum system. Here we calculate the dynamics of a higher-order soliton in the mesoscopic case of $N = 1 0^{3} - 1 0^{4}$ particles, giving predictions for quantum soliton breather relaxation. These quantum predictions use a truncated Wigner approximation, which is a $1/ N$ expansion, in a regime where other exactly known predictions are recovered to high accuracy. Such dynamical calculations are testable in forthcoming BEC experiments.

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