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Condensate induced transitions between topologically ordered phases

F. A. Bais, J. K. Slingerland

TL;DR

The paper develops a comprehensive framework for transitions between 2D topologically ordered phases induced by the condensation of a bosonic quasiparticle, extending symmetry-breaking concepts to the setting of modular tensor categories and quantum groups. It formalizes condensation through branching rules and confinement, yielding the spectrum of non-confined excitations and the effective low-energy theory, while preserving central charge and total quantum dimension in a controlled way. A central theme is the duality between quantum-group symmetry breaking and conformal extensions, with clear connections to well-known CFT constructions such as coset models, conformal embeddings, and orbifolds. The framework is illustrated with detailed examples (notably SU(2)_4 breaking to SU(3)_1 and Maverick cosets), and is shown to reproduce and illuminate a wide range of topological phenomena, including discrete gauge theories, doubled Chern–Simons theories, and boundary theories across phase interfaces. The results have potential implications for realizing and controlling non-Abelian anyons in quantum Hall systems and other platforms, and for guiding the construction of new CFTs from topological data.

Abstract

We investigate transitions between topologically ordered phases in two spatial dimensions induced by the condensation of a bosonic quasiparticle. To this end, we formulate an extension of the theory of symmetry breaking phase transitions which applies to phases with topological excitations described by quantum groups or modular tensor categories. This enables us to deal with phases whose quasiparticles have non-integer quantum dimensions and obey braid statistics. Many examples of such phases can be constructed from two-dimensional rational conformal field theories and we find that there is a beautiful connection between quantum group symmetry breaking and certain well-known constructions in conformal field theory, notably the coset construction, the construction of orbifold models and more general conformal extensions. Besides the general framework, many representative examples are worked out in detail.

Condensate induced transitions between topologically ordered phases

TL;DR

The paper develops a comprehensive framework for transitions between 2D topologically ordered phases induced by the condensation of a bosonic quasiparticle, extending symmetry-breaking concepts to the setting of modular tensor categories and quantum groups. It formalizes condensation through branching rules and confinement, yielding the spectrum of non-confined excitations and the effective low-energy theory, while preserving central charge and total quantum dimension in a controlled way. A central theme is the duality between quantum-group symmetry breaking and conformal extensions, with clear connections to well-known CFT constructions such as coset models, conformal embeddings, and orbifolds. The framework is illustrated with detailed examples (notably SU(2)_4 breaking to SU(3)_1 and Maverick cosets), and is shown to reproduce and illuminate a wide range of topological phenomena, including discrete gauge theories, doubled Chern–Simons theories, and boundary theories across phase interfaces. The results have potential implications for realizing and controlling non-Abelian anyons in quantum Hall systems and other platforms, and for guiding the construction of new CFTs from topological data.

Abstract

We investigate transitions between topologically ordered phases in two spatial dimensions induced by the condensation of a bosonic quasiparticle. To this end, we formulate an extension of the theory of symmetry breaking phase transitions which applies to phases with topological excitations described by quantum groups or modular tensor categories. This enables us to deal with phases whose quasiparticles have non-integer quantum dimensions and obey braid statistics. Many examples of such phases can be constructed from two-dimensional rational conformal field theories and we find that there is a beautiful connection between quantum group symmetry breaking and certain well-known constructions in conformal field theory, notably the coset construction, the construction of orbifold models and more general conformal extensions. Besides the general framework, many representative examples are worked out in detail.

Paper Structure

This paper contains 32 sections, 43 equations, 3 figures, 20 tables.

Table of Contents

  1. Introduction
  2. Setting the stage
  3. Fusion rules, spin and monodromy
  4. Quantum dimensions and modular group
  5. Contact with experiment
  6. From fusion and spin to a full TQFT
  7. On Bosons
  8. Examples
  9. Non-Abelian Hall states
  10. Non-chiral theories
  11. Condensation, Symmetry Breaking and Confinement
  12. Symmetry Breaking: Branching Rules and Physical Requirements
  13. Example: breaking $\mathbf{SU(2)_4}$.
  14. Confinement
  15. Back to the $\mathbf{SU(2)_4}$ example
  16. ...and 17 more sections

Figures (3)

  • Figure 1: A schematic of quantum group symmetry breaking. After breaking we arrive at an intermediate algebra $\mathcal{T}$ that may have irreps which are in fact confined. The low energy effective theory of the condensed phase is based on the unconfined algebra $\mathcal{U}$.
  • Figure 2: A geometry with an interface between two topological phases related by the proposed breaking mechanism. In the inner region there is an unbroken phase, while the outer region is in a broken phase. The interface states correspond to the representations that are confined in the outer region (i.e. the $1$ and $3$ representations of $SU(2)_4$). The states on the outer edge belong to representations that are not confined in the outer region (the $3$ and the $3^{*}$ of $SU(3)_1$).
  • Figure 3: The ribbon equation, relating fusion to topological spin and monodromy.