Bosonic topological phases of matter: bulk-boundary correspondence, SPT invariants and gauging

TL;DR

This paper explores bosonic SPT phases in 2+1d and 3+1d, using bulk response theories and boundary anomalies to define topological invariants, gauge these phases, and analyze their boundary-bulk correspondence.

Contribution

It introduces a dual bulk-boundary framework for classifying and computing invariants of bosonic SPT phases, including gauging procedures and anomaly cancellation methods.

Findings

Defined topological invariants via response actions on manifolds.

Connected gauging of SPTs to anyon condensation and defect proliferation.

Constructed bulk invariants from boundary theories and analyzed mixed anomalies.

Abstract

We analyze $2+1d$ and $3+1d$ Bosonic Symmetry Protected Topological (SPT) phases of matter protected by onsite symmetry group $G$ by using dual bulk and boundary approaches. In the bulk we study an effective field theory which upon coupling to a background flat $G$ gauge field furnishes a purely topological response theory. The response action evaluated on certain manifolds, with appropriate choice of background gauge field, defines a set of SPT topological invariants. Further, SPTs can be gauged by summing over all isomorphism classes of flat $G$ gauge fields to obtain Dijkgraaf-Witten topological $G$ gauge theories. These topological gauge theories can be ungauged by first introducing and then proliferating defects that spoils the gauge symmetry. This mechanism is related to anyon condensation in $2+1d$ and condensing bosonic gauge charges in $3+1d$. In the dual boundary approach, we study $1+1d$ and $2+1d$ quantum field theories that have $G$ 't-Hooft anomalies that can be precisely cancelled by (the response theory of) the corresponding bulk SPT. We show how to construct/compute topological invariants for the bulk SPTs directly from the boundary theories. Further we sum over boundary partition functions with different background gauge fields to construct $G$-characters that generate topological data for the bulk topological gauge theory. Finally, we study a $2+1d$ quantum field theory with a mixed $\mathbb{Z}_2^{T/R} \times U(1)$ anomaly where $\mathbb{Z}_2^{T/R}$ is time-reversal/reflection symmetry, and the $U(1)$ could be a 0-form or 1-form symmetry depending on the choice of time reversal/reflection action. We briefly discuss the bulk effective action and topological response for a theory in $3+1d$ that cancels this anomaly. This signals the existence of SPTs in $3+1d$ protected by 0,1-form $U(1)\times \mathbb{Z}_{2}^{T,R}$.