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Quantum neural network approach to Markovian dissipative dynamics of many-body open quantum systems

Cun Long, Long Cao, Liwei Ge, Qunxiang Li, YiJing Yan, Rui‐Xue Xu, Yao Wang, Xiao Zheng

2024The Journal of Chemical Physics11 citationsDOI

Abstract

Numerous variational methods have been proposed for solving quantum many-body systems, but they often face exponentially increasing computational complexity as the Hilbert space dimension grows. To address this, we introduce a novel approach using quantum neural networks to simulate the dissipative dynamics of many-body open quantum systems. This method combines neural-network quantum state representation with the time-dependent variational principle, both implemented via quantum algorithms. This results in accurate open quantum dynamics described by the Lindblad quantum master equation, exemplified by the spin-boson and transverse field Ising models. Our approach avoids the computational expense of classical algorithms and demonstrates the potential advantages of quantum computing for many-body simulations. To reduce measurement errors, we introduce a projection reset procedure, which could benefit other quantum simulations. In addition, our approach can be extended to simulate non-Markovian quantum dynamics.

Topics & Concepts

Quantum dynamicsOpen quantum systemQuantum networkQuantum algorithmQuantumQuantum processStatistical physicsQuantum simulatorQuantum operationComputer scienceQuantum error correctionQuantum informationQuantum dissipationQuantum statePhysicsQuantum mechanicsQuantum many-body systemsQuantum Computing Algorithms and ArchitectureSpectroscopy and Quantum Chemical Studies
Quantum neural network approach to Markovian dissipative dynamics of many-body open quantum systems | Litcius