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Theory and classification of interacting 'integer' topological phases in two dimensions: A Chern-Simons approach

Yuan-Ming Lu, Ashvin Vishwanath

TL;DR

<p>The paper develops a symmetry-aware K-matrix (Chern-Simons) framework to classify interacting 2D phases without topological order, i.e., symmetry-protected topological (SPT) states. By embedding symmetry into edge transformations via GL(N, Z) relabelings and Higgs terms, it reproduces the group-cohomology classifications for a broad set of symmetries and provides explicit edge theories and coupled-wire constructions. It extends to interacting fermions with projective symmetry actions, uncovering Z2, Z4, and Z2^2 type classifications and connecting them to both bosonic SPT phases and fermionic band-structure insights. The coupled-wire realizations illuminate concrete microscopic routes to realize these phases and highlight how disorder remains compatible with the SPT distinctions, offering a path toward experimental relevance in 2D systems.</p>

Abstract

We study topological phases of interacting systems in two spatial dimensions in the absence of topological order (i.e. with a unique ground state on closed manifolds and no fractional excitations). These are the closest interacting analogs of integer Quantum Hall states, topological insulators and superconductors. We adapt the well-known Chern-Simons {K}-matrix description of Quantum Hall states to classify such `integer' topological phases. Our main result is a general formalism that incorporates symmetries into the {K}-matrix description. Remarkably, this simple analysis yields the same list of topological phases as a recent group cohomology classification, and in addition provides field theories and explicit edge theories for all these phases. The bosonic topological phases, which only appear in the presence of interactions and which remain well defined in the presence of disorder include (i) bosonic insulators with a Hall conductance quantized to even integers (ii) a bosonic analog of quantum spin Hall insulators and (iii) a bosonic analog of a chiral topological superconductor, whose K matrix is the Cartan matrix of Lie group E$_8$. We also discuss interacting fermion systems where symmetries are realized in a projective fashion, where we find the present formalism can handle a wider range of symmetries than a recent group super-cohomology classification. Lastly we construct microscopic models of these phases from coupled one-dimensional systems.

Theory and classification of interacting 'integer' topological phases in two dimensions: A Chern-Simons approach

TL;DR

<p>The paper develops a symmetry-aware K-matrix (Chern-Simons) framework to classify interacting 2D phases without topological order, i.e., symmetry-protected topological (SPT) states. By embedding symmetry into edge transformations via GL(N, Z) relabelings and Higgs terms, it reproduces the group-cohomology classifications for a broad set of symmetries and provides explicit edge theories and coupled-wire constructions. It extends to interacting fermions with projective symmetry actions, uncovering Z2, Z4, and Z2^2 type classifications and connecting them to both bosonic SPT phases and fermionic band-structure insights. The coupled-wire realizations illuminate concrete microscopic routes to realize these phases and highlight how disorder remains compatible with the SPT distinctions, offering a path toward experimental relevance in 2D systems.</p>

Abstract

We study topological phases of interacting systems in two spatial dimensions in the absence of topological order (i.e. with a unique ground state on closed manifolds and no fractional excitations). These are the closest interacting analogs of integer Quantum Hall states, topological insulators and superconductors. We adapt the well-known Chern-Simons {K}-matrix description of Quantum Hall states to classify such `integer' topological phases. Our main result is a general formalism that incorporates symmetries into the {K}-matrix description. Remarkably, this simple analysis yields the same list of topological phases as a recent group cohomology classification, and in addition provides field theories and explicit edge theories for all these phases. The bosonic topological phases, which only appear in the presence of interactions and which remain well defined in the presence of disorder include (i) bosonic insulators with a Hall conductance quantized to even integers (ii) a bosonic analog of quantum spin Hall insulators and (iii) a bosonic analog of a chiral topological superconductor, whose K matrix is the Cartan matrix of Lie group E. We also discuss interacting fermion systems where symmetries are realized in a projective fashion, where we find the present formalism can handle a wider range of symmetries than a recent group super-cohomology classification. Lastly we construct microscopic models of these phases from coupled one-dimensional systems.

Paper Structure

This paper contains 53 sections, 201 equations, 2 figures, 2 tables.

Table of Contents

  1. Introduction
  2. $K$ matrix formulation of $2+1$-D topological phases
  3. A brief review of the $K$ matrix formulation
  4. $K$ matrix + Higgs formulation
  5. A chiral bosonic phase without topological order: The $E_8$ state
  6. Incorporating symmetries in $K$ matrix formulation
  7. $K$-matrix classification of bosonic SPT phases
  8. $Z_2^T$ symmetry: ${\mathbb{Z}}_1$ class
  9. $U(1)$ symmetry: ${\mathbb{Z}}$ classes
  10. $U(1)\rtimes Z_2^T$ symmetry: ${\mathbb{Z}}_2$ classes
  11. $Z_N$ symmetry: ${\mathbb{Z}}_N$ classes
  12. $N=$ odd integer: ${\mathbb{Z}}_N$ classes
  13. $N=$ even integer: ${\mathbb{Z}}_N$ classes
  14. $N=$ even integer: other solutions
  15. $Z_N\rtimes Z_2^T$ symmetry
  16. ...and 38 more sections

Figures (2)

  • Figure 1: Summary of some simple 'integer' bosonic topological phases. 1) A chiral phase of bosons (no symmetry required). An integer multiple of eight chiral bosons at the edge is needed to evade topological order, leading to a quantized thermal Hall conductance $\kappa_{xy}/T=8nL_0$ in units of the the universal thermal conductance $L_0=\frac{\pi^2k_B^2}{3h}$. These are bosonic analogs of chiral superconductors. (2) A non-chiral phase of bosons protected by $U(1)$ symmetry (eg. charge conservation). Distinct phases can be labeled by the quantized Hall conductance $\sigma_{xy}=2n\sigma_0$, which are even integer multiples of the universal conductance $\sigma_0=q^2/h$ for particles with charge $q$. These are bosonic analogs of the integer quantum Hall phases. (3) a non-chiral phase stabilized in the presence of time reversal and $U(1)$ charge conservation symmetries, the same symmetries used to define quantum spin Hall (topological) insulators. A $Z_2$ topological classification is obtained, although bosonic time reversal that squares to $+1$ is involved.
  • Figure 2: Schematic illustration of interwire coupling terms which stabilize the bosonic SPT phases protected by $U(1)$ symmetry, with Hall conductance $\sigma_{xy}=2q$. Solid horizontal lines stand for quantum wires of charged bosons (each carries unit $U(1)$ charge) while dashed horizontal lines represent quantum wires composed of neutral (say spin) degrees of freedom. Dashed and solid arrows illustrate the two interwire coupling terms in (\ref{['interwire:U(1)']}) that gap the bulk, but leave behind nontrivial edge states.