Related papers: Rapid quantum ground state preparation via dissipative dynamics

Rapid quantum ground state preparation via dissipative dynamics

URL: http://arxiv.org/abs/2503.15827v2
Date: Fri, 04 Apr 2025 17:12:09 GMT
Title: Rapid quantum ground state preparation via dissipative dynamics
Authors: Yongtao Zhan, Zhiyan Ding, Jakob Huhn, Johnnie Gray, John Preskill, Garnet Kin-Lic Chan, Lin Lin,
Abstract summary: dissipation has become a promising approach for preparing low-energy states of quantum systems.<n>However, the potential of dissipative protocols remains unclear beyond certain commuting Hamiltonians.<n>This work provides significant analytical and numerical insights into the power of dissipation for preparing the ground state of non-commuting Hamiltonians.
Score: 3.3187923242469246
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Inspired by natural cooling processes, dissipation has become a promising approach for preparing low-energy states of quantum systems. However, the potential of dissipative protocols remains unclear beyond certain commuting Hamiltonians. This work provides significant analytical and numerical insights into the power of dissipation for preparing the ground state of non-commuting Hamiltonians. For quasi-free dissipative dynamics, including certain 1D spin systems with boundary dissipation, our results reveal a new connection between the mixing time in trace distance and the spectral properties of a non-Hermitian Hamiltonian, leading to an explicit and sharp bound on the mixing time that scales polynomially with system size. For more general spin systems, we develop a tensor network-based algorithm for constructing the Lindblad jump operator and for simulating the dynamics. Using this algorithm, we demonstrate numerically that dissipative ground state preparation protocols can achieve rapid mixing for certain 1D local Hamiltonians under bulk dissipation, with a mixing time that scales logarithmically with the system size. We then prove the rapid mixing result for certain weakly interacting spin and fermionic systems in arbitrary dimensions, extending recent results for high-temperature quantum Gibbs samplers to the zero-temperature regime. Our theoretical approaches are applicable to systems with singular stationary states, and are thus expected to have applications beyond the specific systems considered in this study.

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