Remarks on non-invertible symmetries on a tensor product Hilbert space in 1+1 dimensions

TL;DR

This paper introduces an index for non-invertible symmetries in 1+1 dimensions, relating their realizability on lattice Hilbert spaces and connecting fusion rules with weakly integral categories, using tensor network frameworks.

Contribution

It generalizes the index for invertible symmetries to non-invertible cases, proposes a class of MPOs for these symmetries, and explores their fusion rules and tensor network representations.

Findings

Proposed a generalized index for non-invertible symmetries.

Constructed topological injective MPOs including various symmetry types.

Established conditions under which fusion channels share the same index.

Abstract

We propose an index of non-invertible symmetry operators in 1+1 dimensions and discuss its relation to the realizability of non-invertible symmetries on the tensor product of finite dimensional on-site Hilbert spaces on the lattice. Our index generalizes the Gross-Nesme-Vogts-Werner index of invertible symmetry operators represented by quantum cellular automata (QCAs). Assuming that all fusion channels of symmetry operators have the same index, we show that the fusion rules of finitely many symmetry operators on a tensor product Hilbert space can agree, up to QCAs, only with those of weakly integral fusion categories. We also discuss an attempt to establish an index theory for non-invertible symmetries within the framework of tensor networks. To this end, we first propose a general class of matrix product operators (MPOs) that describe non-invertible symmetries on a tensor product Hilbert space. These MPOs, which we refer to as topological injective MPOs, include all invertible symmetries, non-anomalous fusion category symmetries, and the Kramers-Wannier symmetries for finite abelian groups. For topological injective MPOs, we construct the defect Hilbert spaces and the corresponding sequential quantum circuit representations. We also show that all fusion channels of topological injective MPOs have the same index if there exist fusion and splitting tensors that satisfy appropriate conditions. The existence of such fusion and splitting tensors has not been proven in general, although we construct them explicitly for all examples of topological injective MPOs listed above.