Related papers: Doped stabilizer states in many-body physics and where to find them

Doped stabilizer states in many-body physics and where to find them

URL: http://arxiv.org/abs/2403.14912v2
Date: Thu, 18 Apr 2024 01:43:35 GMT
Title: Doped stabilizer states in many-body physics and where to find them
Authors: Andi Gu, Salvatore F. E. Oliviero, Lorenzo Leone,
Abstract summary: This work uncovers a fundamental connection between doped stabilizer states and the structure of eigenstates in many-body quantum systems. We develop efficient classical algorithms for tasks such as finding low-energy eigenstates, simulating quench dynamics, and computing entanglement entropies in these systems.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: This work uncovers a fundamental connection between doped stabilizer states, a concept from quantum information theory, and the structure of eigenstates in perturbed many-body quantum systems. We prove that for Hamiltonians consisting of a sum of commuting Pauli operators (i.e., stabilizer Hamiltonians) and a perturbation composed of a limited number of arbitrary Pauli terms, the eigenstates can be represented as doped stabilizer states with small stabilizer nullity. This result enables the application of stabilizer techniques to a broad class of many-body systems, even in highly entangled regimes. Building on this, we develop efficient classical algorithms for tasks such as finding low-energy eigenstates, simulating quench dynamics, preparing Gibbs states, and computing entanglement entropies in these systems. Our work opens up new possibilities for understanding the robustness of topological order and the dynamics of many-body systems under perturbations, paving the way for novel insights into the interplay of quantum information, entanglement, and many-body systems.

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