Higher-group structure in 2n-dimensional axion-electrodynamics

Tatsuki Nakajima; Tadakatsu Sakai; Ryo Yokokura

doi:10.1007/JHEP01(2023)150

Higher-group structure in 2n-dimensional axion-electrodynamics

Tatsuki Nakajima, Tadakatsu Sakai, Ryo Yokokura

Faculty of Business and Commerce

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Abstract

We investigate 2n-dimensional axion electrodynamics for the purpose of exploring a higher-group structure underlying it. This is manifested as a Green-Schwarz transformation of the background gauge fields that couple minimally to the conserved currents. The n = 3 case is studied most intensively. We derive the identities of correlation functions among the global symmetry generators by using a gauge transformation that maps two correlation functions with each other. A key ingredient in this computation is given by the Green-Schwarz transformation and the ’t Hooft anomalies associated with the gauge transformation. The algebraic structure of these results and its physical interpretations are discussed in detail. In particular, we find that the higher-group structure for n = 3 is endowed with a multi-ary operation among the symmetry generators.

Original language	English
Article number	150
Journal	Journal of High Energy Physics
Volume	2023
Issue number	1
DOIs	https://doi.org/10.1007/JHEP01(2023)150
Publication status	Published - 2023 Feb

Keywords

Anomalies in Field and String Theories
Field Theories in Higher Dimensions
Global Symmetries

ASJC Scopus subject areas

Nuclear and High Energy Physics

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10.1007/JHEP01(2023)150

Cite this

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title = "Higher-group structure in 2n-dimensional axion-electrodynamics",

abstract = "We investigate 2n-dimensional axion electrodynamics for the purpose of exploring a higher-group structure underlying it. This is manifested as a Green-Schwarz transformation of the background gauge fields that couple minimally to the conserved currents. The n = 3 case is studied most intensively. We derive the identities of correlation functions among the global symmetry generators by using a gauge transformation that maps two correlation functions with each other. A key ingredient in this computation is given by the Green-Schwarz transformation and the {\textquoteright}t Hooft anomalies associated with the gauge transformation. The algebraic structure of these results and its physical interpretations are discussed in detail. In particular, we find that the higher-group structure for n = 3 is endowed with a multi-ary operation among the symmetry generators.",

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AU - Sakai, Tadakatsu

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AB - We investigate 2n-dimensional axion electrodynamics for the purpose of exploring a higher-group structure underlying it. This is manifested as a Green-Schwarz transformation of the background gauge fields that couple minimally to the conserved currents. The n = 3 case is studied most intensively. We derive the identities of correlation functions among the global symmetry generators by using a gauge transformation that maps two correlation functions with each other. A key ingredient in this computation is given by the Green-Schwarz transformation and the ’t Hooft anomalies associated with the gauge transformation. The algebraic structure of these results and its physical interpretations are discussed in detail. In particular, we find that the higher-group structure for n = 3 is endowed with a multi-ary operation among the symmetry generators.

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Higher-group structure in 2n-dimensional axion-electrodynamics

Abstract

Keywords

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