Lindbladian Simulation with Commutator Bounds
Abstract
Trotter decomposition provides a simple approach to simulating open quantum systems by decomposing the Lindbladian into a sum of individual terms. While it is established that Trotter errors in Hamiltonian simulation depend on nested commutators of the summands, such a relationship remains poorly understood for Lindbladian dynamics. In this Letter, we derive commutator-based Trotter error bounds for Lindbladian simulation, yielding an scaling in the number of Trotter steps for locally interacting systems on sites. When estimating observable averages, we apply Richardson extrapolation to achieve polylogarithmic precision while maintaining the commutator scaling. To bound the extrapolation remainder, we develop a general truncation bound for the Baker-Campbell-Hausdorff expansion that bypasses common convergence issues in physically relevant systems. For local Lindbladians, our results demonstrate that the Trotter-based methods outperform prior simulation techniques in system-size scaling while requiring only ancillas. Numerical simulations further validate the predicted system-size and precision scaling.
Cite
@article{arxiv.2603.28602,
title = {Lindbladian Simulation with Commutator Bounds},
author = {Xinzhao Wang and Shuo Zhou and Xiaoyang Wang and Yi-Cong Zheng and Shengyu Zhang and Tongyang Li},
journal= {arXiv preprint arXiv:2603.28602},
year = {2026}
}
Comments
29 pages, 4 figures