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Symmetry and Topological Order

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arxiv cond-mat/0605316 v3 pith:GV4XL7F2 submitted 2006-05-12 cond-mat.str-el cond-mat.stat-mechhep-thmath-phmath.MPquant-ph

Symmetry and Topological Order

classification cond-mat.str-el cond-mat.stat-mechhep-thmath-phmath.MPquant-ph
keywords topologicalsymmetriesorderquantumgauge-likesymmetryassociatedspin
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We prove sufficient conditions for Topological Quantum Order at both zero and finite temperatures. The crux of the proof hinges on the existence of low-dimensional Gauge-Like Symmetries (that notably extend and differ from standard local gauge symmetries) and their associated defects, thus providing a unifying framework based on a symmetry principle. These symmetries may be actual invariances of the system, or may emerge in the low-energy sector. Prominent examples of Topological Quantum Order display Gauge-Like Symmetries. New systems exhibiting such symmetries include Hamiltonians depicting orbital-dependent spin exchange and Jahn-Teller effects in transition metal orbital compounds, short-range frustrated Klein spin models, and p+ip superconducting arrays. We analyze the physical consequences of Gauge-Like Symmetries (including topological terms and charges), discuss associated braiding, and show the insufficiency of the energy spectrum, topological entanglement entropy, maximal string correlators, and fractionalization in establishing Topological Quantum Order. General symmetry considerations illustrate that not withstanding spectral gaps, thermal fluctuations may impose restrictions on certain suggested quantum computing schemes and lead to "thermal fragility". Our results allow us to go beyond standard topological field theories and engineer systems with Topological Quantum Order.

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Cited by 3 Pith papers

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    Statistics of G-conserved invertible mixed-dimensional excitations in d-space are classified by H^{d+2}(BG; R/Z) and realized as boundary excitations of an ω-twisted higher-group gauge theory.

  2. 3-Crossed Module Structure in the Five-Dimensional Topological Axion Electrodynamics

    hep-th 2026-02 unverdicted novelty 6.0

    The five-dimensional topological axion electrodynamics is shown to possess a 3-crossed module structure through modified Stueckelberg couplings required for background gauge invariance.

  3. Mixed-state topological order and the errorfield double formulation of decoherence-induced transitions

    quant-ph 2023-01 unverdicted novelty 6.0

    Decoherence on abelian topological order is modeled as a temporal defect in double TQFT driving boundary anyon condensation transitions classified by Lagrangian subgroups of the doubled order.