Disentangling critical quantum spin chains with Clifford circuits

Clifford circuits can be utilized to disentangle quantum state with polynomial cost, thanks to the Gottesman-Knill theorem. Based on this idea, Clifford Circuits Augmented Matrix Product States (CAMPS) method, which is a seamless integration of Clifford circuits within the DMRG algorithm, was propos...

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Hauptverfasser: Fan, Chaohui, Qian, Xiangjian, Zhang, Hua-Chen, Huang, Rui-Zhen, Qin, Mingpu, Xiang, Tao
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Sprache:eng
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Zusammenfassung:Clifford circuits can be utilized to disentangle quantum state with polynomial cost, thanks to the Gottesman-Knill theorem. Based on this idea, Clifford Circuits Augmented Matrix Product States (CAMPS) method, which is a seamless integration of Clifford circuits within the DMRG algorithm, was proposed recently and was shown to be able to reduce entanglement in various quantum systems. In this work, we further explore the power of CAMPS method in critical spin chains described by conformal field theories (CFTs) in the scaling limit. We find that the variationally optimized disentangler corresponds to {\it duality} transformations, which significantly reduce the entanglement entropy in the ground state. For critical quantum Ising spin chain governed by the Ising CFT with self-duality, the Clifford circuits found by CAMPS coincide with the duality transformation, e.g., the Kramer-Wannier self-duality in the critical Ising chain. It reduces the entanglement entropy by mapping the free conformal boundary condition to the fixed one. In the more general case of XXZ chain, the CAMPS gives rise to a duality transformation mapping the model to the quantum Ashkin-Teller spin chain. Our results highlight the potential of CAMPS as a versatile tool for uncovering hidden dualities and simplifying the entanglement structure of critical quantum systems.
DOI:10.48550/arxiv.2411.12683