Lattice realization of the axial U(1) non-invertible symmetry

IF 3.5 4区物理与天体物理 Q1 Physics and Astronomy

Progress of Theoretical and Experimental Physics Pub Date : 2024-03-13 DOI:10.1093/ptep/ptae040

Yamato Honda, Okuto Morikawa, Soma Onoda, Hiroshi Suzuki

引用次数: 0

Abstract

In U(1) lattice gauge theory with compact U(1) variables, we construct the symmetry operator, i.e., the topological defect, for the axial U(1) non-invertible symmetry. This requires a lattice formulation of chiral gauge theory with an anomalous matter content and we employ the lattice formulation on the basis of the Ginsparg–Wilson relation. The invariance of the symmetry operator under the gauge transformation of the gauge field on the defect is realized, imitating the prescription by Karasik in continuum theory, by integrating the lattice Chern–Simons term on the defect over smooth lattice gauge transformations. The projection operator for allowed magnetic fluxes on the defect then emerges with lattice regularization. The resulting symmetry operator is manifestly invariant under lattice gauge transformations. In an appendix, we give another way of constructing the symmetry operator on the basis of a 3D $\mathbb {Z}_N$ TQFT, the level-N BF theory on the lattice.

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轴 U(1) 不可逆对称的晶格实现

在具有紧凑U(1) 变量的U(1) 格规理论中，我们为轴U(1) 不可逆对称构造了对称算子，即拓扑缺陷。这需要一种具有反常物质含量的手性规规理论晶格公式，我们在金斯帕-威尔逊关系的基础上采用了晶格公式。仿照卡拉希克在连续理论中的处方，通过对缺陷上的晶格切尔-西蒙斯项进行平滑晶格量规变换积分，实现了对称算子在缺陷上量规场的量规变换下的不变性。这样，缺陷上允许磁通量的投影算子就通过晶格正则化出现了。由此得到的对称算子在晶格轨距变换下是明显不变的。在附录中，我们给出了在三维 $\mathbb {Z}_N$ TQFT（晶格上的 N 层 BF 理论）基础上构造对称算子的另一种方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Progress of Theoretical and Experimental Physics PHYSICS, MULTIDISCIPLINARY-PHYSICS, PARTICLES & FIELDS

CiteScore

12.00

自引率

5.70%

发文量

148

审稿时长

17 weeks

期刊介绍： Progress of Theoretical and Experimental Physics (PTEP) is an international journal that publishes articles on theoretical and experimental physics. PTEP is a fully open access, online-only journal published by the Physical Society of Japan. PTEP is the successor to Progress of Theoretical Physics (PTP), which terminated in December 2012 and merged into PTEP in January 2013. PTP was founded in 1946 by Hideki Yukawa, the first Japanese Nobel Laureate. PTEP, the successor journal to PTP, has a broader scope than that of PTP covering both theoretical and experimental physics. PTEP mainly covers areas including particles and fields, nuclear physics, astrophysics and cosmology, beam physics and instrumentation, and general and mathematical physics.