Simulation of open quantum systems on universal quantum computers
Abstract
The rapid development of quantum computers has enabled demonstrations of quantum advantages on various tasks. However, real quantum systems are always dissipative due to their inevitable interaction with the environment, and the resulting non-unitary dynamics make quantum simulation challenging with only unitary quantum gates. In this work, we present an innovative and scalable method to simulate open quantum systems using quantum computers. We define an adjoint density matrix as a counterpart of the true density matrix, which reduces to a mixed-unitary quantum channel and thus can be effectively sampled using quantum computers. This method has several benefits, including no need for auxiliary qubits and noteworthy scalability. Moreover, some long-time properties like steady states and the thermal equilibrium can also be investigated as the adjoint density matrix and the true dissipated one converge to the same state. Finally, we present deployments of this theory in the dissipative quantum model for the evolution of correlation and entropy with short-time dynamics and the disordered Heisenberg model for many-body localization with long-time dynamics. This work promotes the study of real-world many-body dynamics with quantum computers, highlighting the potential to demonstrate practical quantum advantages.
Cite
@article{arxiv.2405.20712,
title = {Simulation of open quantum systems on universal quantum computers},
author = {Huan-Yu Liu and Xiaoshui Lin and Zhao-Yun Chen and Cheng Xue and Tai-Ping Sun and Qing-Song Li and Xi-Ning Zhuang and Yun-Jie Wang and Yu-Chun Wu and Ming Gong and Guo-Ping Guo},
journal= {arXiv preprint arXiv:2405.20712},
year = {2025}
}
Comments
20 pages, 7 figures