A many-body winding invariant based on Pancharatnam phases uniquely determines the 4^ν entanglement-spectrum degeneracy scaling in interacting generalized SSH chains, establishing symmetry-protected bulk-boundary correspondence.
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Numerical simulations reveal that anyonic statistics phase and synthetic gauge flux induce asymmetric transport, dynamical symmetries, and tunable chiral or antichiral expansion dynamics in interacting two-component anyon-Hubbard models.
A review summarizing theoretical and experimental progress on disorder-induced topological phases including TAIs, quasiperiodic extensions, non-Hermitian systems, and many-body realizations.
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Symmetry Protected Bulk-Boundary Correspondence in Interacting Topological Insulators
A many-body winding invariant based on Pancharatnam phases uniquely determines the 4^ν entanglement-spectrum degeneracy scaling in interacting generalized SSH chains, establishing symmetry-protected bulk-boundary correspondence.
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Asymmetric and chiral dynamics of two-component anyons with synthetic gauge flux
Numerical simulations reveal that anyonic statistics phase and synthetic gauge flux induce asymmetric transport, dynamical symmetries, and tunable chiral or antichiral expansion dynamics in interacting two-component anyon-Hubbard models.
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Recent progress on disorder-induced topological phases
A review summarizing theoretical and experimental progress on disorder-induced topological phases including TAIs, quasiperiodic extensions, non-Hermitian systems, and many-body realizations.