Generalized global symmetries View Full Text


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Article Info

DATE

2015-02

AUTHORS

Davide Gaiotto, Anton Kapustin, Nathan Seiberg, Brian Willett

ABSTRACT

A q-form global symmetry is a global symmetry for which the charged operators are of space-time dimension q; e.g. Wilson lines, surface defects, etc., and the charged excitations have q spatial dimensions; e.g. strings, membranes, etc. Many of the properties of ordinary global symmetries (q = 0) apply here. They lead to Ward identities and hence to selection rules on amplitudes. Such global symmetries can be coupled to classical background fields and they can be gauged by summing over these classical fields. These generalized global symmetries can be spontaneously broken (either completely or to a sub-group). They can also have ’t Hooft anomalies, which prevent us from gauging them, but lead to ’t Hooft anomaly matching conditions. Such anomalies can also lead to anomaly inflow on various defects and exotic Symmetry Protected Topological phases. Our analysis of these symmetries gives a new unified perspective of many known phenomena and uncovers new results. More... »

PAGES

172

References to SciGraph publications

  • 2010-07. Modifying the sum over topological sectors and constraints on supergravity in JOURNAL OF HIGH ENERGY PHYSICS
  • 1989-09. Quantum field theory and the Jones polynomial in COMMUNICATIONS IN MATHEMATICAL PHYSICS
  • 2009-06-03. Comments on the Fayet-Iliopoulos term in field theory and supergravity in JOURNAL OF HIGH ENERGY PHYSICS
  • 1985-07. Higher regulators and values of L-functions in JOURNAL OF SOVIET MATHEMATICS
  • 2011-07. Supercurrents and brane currents in diverse dimensions in JOURNAL OF HIGH ENERGY PHYSICS
  • 1971-12. Théorie de Hodge, II in PUBLICATIONS MATHÉMATIQUES DE L'IHÉS
  • 2001-10-04. D-brane charges in five-brane backgrounds in JOURNAL OF HIGH ENERGY PHYSICS
  • 2013-08. Reading between the lines of four-dimensional gauge theories in JOURNAL OF HIGH ENERGY PHYSICS
  • 2007-04. The Uncertainty of Fluxes in COMMUNICATIONS IN MATHEMATICAL PHYSICS
  • 1990-04. Topological gauge theories and group cohomology in COMMUNICATIONS IN MATHEMATICAL PHYSICS
  • 2014-04. Coupling a QFT to a TQFT and duality in JOURNAL OF HIGH ENERGY PHYSICS
  • 2011-06. Charge lattices and consistency of 6D supergravity in JOURNAL OF HIGH ENERGY PHYSICS
  • 1949-12. On simply connected, 4-dimensional polyhedra in COMMENTARII MATHEMATICI HELVETICI
  • 1985. Differential characters and geometric invariants in GEOMETRY AND TOPOLOGY
  • 2003-02-19. Phases of 𝒩 = 1 supersymmetric gauge theories in JOURNAL OF HIGH ENERGY PHYSICS
  • Identifiers

    URI

    http://scigraph.springernature.com/pub.10.1007/jhep02(2015)172

    DOI

    http://dx.doi.org/10.1007/jhep02(2015)172

    DIMENSIONS

    https://app.dimensions.ai/details/publication/pub.1045360529


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        "description": "A q-form global symmetry is a global symmetry for which the charged operators are of space-time dimension q; e.g. Wilson lines, surface defects, etc., and the charged excitations have q spatial dimensions; e.g. strings, membranes, etc. Many of the properties of ordinary global symmetries (q = 0) apply here. They lead to Ward identities and hence to selection rules on amplitudes. Such global symmetries can be coupled to classical background fields and they can be gauged by summing over these classical fields. These generalized global symmetries can be spontaneously broken (either completely or to a sub-group). They can also have \u2019t Hooft anomalies, which prevent us from gauging them, but lead to \u2019t Hooft anomaly matching conditions. Such anomalies can also lead to anomaly inflow on various defects and exotic Symmetry Protected Topological phases. Our analysis of these symmetries gives a new unified perspective of many known phenomena and uncovers new results.", 
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