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Main Authors: Lee, Chanbeen, Hu, Yaozong, Cho, Gil Young, Watanabe, Haruki
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2504.09847
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author Lee, Chanbeen
Hu, Yaozong
Cho, Gil Young
Watanabe, Haruki
author_facet Lee, Chanbeen
Hu, Yaozong
Cho, Gil Young
Watanabe, Haruki
contents In this work, we generalize several three-dimensional Z2 stabilizer models--including the X-cube model, the three-dimensional toric code, and Haah's code--to their ZN counterparts. Under periodic boundary conditions, we analyze their ground state degeneracies and topological excitations, and uncover behaviors that strongly depend on system size. For the X-cube model, we identify excitations with mobility restricted under local operations but relaxed under nonlocal ones derived from global topology. These excitations, previously confined to open boundaries in the Z2 model, now appear even under periodic boundaries. In the toric code, we observe nontrivial braiding between string and point excitations despite the absence of ground state degeneracy, indicating long-range entanglement independent of topological degeneracy. Again, this effect extends from open to periodic boundaries in the generalized models. For Haah's code, we find new excitations--fracton tripoles and monopoles--that remain globally constrained, along with a relaxation of immobility giving rise to lineons and planons. These results reveal new forms of topological order and suggest a broader framework for understanding fracton phases beyond the conventional Z2 setting.
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publishDate 2025
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spellingShingle $\mathbb{Z}_N$ generalizations of three-dimensional stabilizer codes
Lee, Chanbeen
Hu, Yaozong
Cho, Gil Young
Watanabe, Haruki
Strongly Correlated Electrons
In this work, we generalize several three-dimensional Z2 stabilizer models--including the X-cube model, the three-dimensional toric code, and Haah's code--to their ZN counterparts. Under periodic boundary conditions, we analyze their ground state degeneracies and topological excitations, and uncover behaviors that strongly depend on system size. For the X-cube model, we identify excitations with mobility restricted under local operations but relaxed under nonlocal ones derived from global topology. These excitations, previously confined to open boundaries in the Z2 model, now appear even under periodic boundaries. In the toric code, we observe nontrivial braiding between string and point excitations despite the absence of ground state degeneracy, indicating long-range entanglement independent of topological degeneracy. Again, this effect extends from open to periodic boundaries in the generalized models. For Haah's code, we find new excitations--fracton tripoles and monopoles--that remain globally constrained, along with a relaxation of immobility giving rise to lineons and planons. These results reveal new forms of topological order and suggest a broader framework for understanding fracton phases beyond the conventional Z2 setting.
title $\mathbb{Z}_N$ generalizations of three-dimensional stabilizer codes
topic Strongly Correlated Electrons
url https://arxiv.org/abs/2504.09847