具有非不可逆对称性的 (2+1)d 中的空隙相位:第一部分

Lakshya Bhardwaj, Daniel Pajer, Sakura Schafer-Nameki, Apoorv Tiwari, Alison Warman, Jingxiang Wu
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摘要

我们使用对称拓扑场理论(SymTFT)来研究和分类一类分类对称(被称为玻色类型)的(2+1)d中的隙相。这些对称性的 SymTFTs 是由有限群 G 的扭曲和非扭曲 (3+1)d Dijkgraaf-Witten (DW) 理论给出的。这些 DW 理论的边界条件(BCs)是众所周知的:这些条件只涉及对 (3+1)dge 场施加 Dirichlet 和 Neumann 条件。我们把它们称为最小边界条件。这里的关键新发现是,对于每一个DW理论,都存在着无限多的其他BC,我们称之为非最小BC。这些非最小 BC 都是通过 "thetaconstruction "得到的,其中包括用具有 G0 形式对称性的 3d TFT 堆叠 Dirichlet BC,并对对角线 G 对称性进行测量。一方面,使用非最小 BC 作为对称 BC 会产生无数个具有相同 SymTFT 的非不可逆对称;另一方面,在三明治结构中使用非最小 BC 作为物理 BC 会为每个非不可逆对称产生无数个 (2+1)d 间隙相。我们的分析对 G = $\mathbb{Z_2}$ 以及更广义的任何有限无性群都做了详尽的举例说明,由此产生的非不对称及其间隙相已经揭示了极其丰富的结构。
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Gapped Phases in (2+1)d with Non-Invertible Symmetries: Part I
We use the Symmetry Topological Field Theory (SymTFT) to study and classify gapped phases in (2+1)d for a class of categorical symmetries, referred to as being of bosonic type. The SymTFTs for these symmetries are given by twisted and untwisted (3+1)d Dijkgraaf-Witten (DW) theories for finite groups G. A finite set of boundary conditions (BCs) of these DW theories is well-known: these simply involve imposing Dirichlet and Neumann conditions on the (3+1)d gauge fields. We refer to these as minimal BCs. The key new observation here is that for each DW theory, there exists an infinite number of other BCs, that we call non-minimal BCs. These non-minimal BCs are all obtained by a 'theta construction', which involves stacking the Dirichlet BC with 3d TFTs having G 0-form symmetry, and gauging the diagonal G symmetry. On the one hand, using the non-minimal BCs as symmetry BCs gives rise to an infinite number of non-invertible symmetries having the same SymTFT, while on the other hand, using the non-minimal BCs as physical BCs in the sandwich construction gives rise to an infinite number of (2+1)d gapped phases for each such non-invertible symmetry. Our analysis is thoroughly exemplified for G = $\mathbb{Z_2}$ and more generally any finite abelian group, for which the resulting non-invertible symmetries and their gapped phases already reveal an immensely rich structure.
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