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Hauptverfasser: Wang, X., Wu, X. F., Yang, B., Zhang, B., Xiong, B.
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2412.03114
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author Wang, X.
Wu, X. F.
Yang, B.
Zhang, B.
Xiong, B.
author_facet Wang, X.
Wu, X. F.
Yang, B.
Zhang, B.
Xiong, B.
contents Understanding the mechanism behind the buildup of inner correlations is crucial for studying nonequilibrium dynamics in complex, strongly interacting many-body systems. Here we investigate both analytically and numerically the buildup of antiferromagnetic (AF) correlations in a dynamically tuned Ising model with various geometries, realized in a Rydberg atomic system. Through second-order Magnus expansion (ME), we demonstrate quantitative agreement with numerical simulations for diverse configurations including $2 \times n$ lattice and cyclic lattice with a star. We find that the AF correlation magnitude at fixed Manhattan distance obeys a universal superposition principle: It corresponds to the algebraic sum of contributions from all shortest paths. This superposition law remains robust against variations in path equivalence, lattice geometries, and quench protocols, establishing a new paradigm for correlation propagation in quantum simulators.
format Preprint
id arxiv_https___arxiv_org_abs_2412_03114
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Algebraic law of local correlations in a driven Rydberg atomic system
Wang, X.
Wu, X. F.
Yang, B.
Zhang, B.
Xiong, B.
Quantum Gases
Quantum Physics
Understanding the mechanism behind the buildup of inner correlations is crucial for studying nonequilibrium dynamics in complex, strongly interacting many-body systems. Here we investigate both analytically and numerically the buildup of antiferromagnetic (AF) correlations in a dynamically tuned Ising model with various geometries, realized in a Rydberg atomic system. Through second-order Magnus expansion (ME), we demonstrate quantitative agreement with numerical simulations for diverse configurations including $2 \times n$ lattice and cyclic lattice with a star. We find that the AF correlation magnitude at fixed Manhattan distance obeys a universal superposition principle: It corresponds to the algebraic sum of contributions from all shortest paths. This superposition law remains robust against variations in path equivalence, lattice geometries, and quench protocols, establishing a new paradigm for correlation propagation in quantum simulators.
title Algebraic law of local correlations in a driven Rydberg atomic system
topic Quantum Gases
Quantum Physics
url https://arxiv.org/abs/2412.03114