Topologically ordered phase states: from knots and braids to quantum dimers

TL;DR

This paper explores the topological order in systems with macroscopic ground state degeneracy, linking knot theory, quantum groups, and generalized exclusion statistics to construct quantum dimer models.

Contribution

It introduces a novel approach connecting topological order, quantum group representations, and knotted field configurations to model quantum dimers.

Findings

Exact solutions are quantum dimensions of quantum group representations.

Demonstrates the intersection of exclusion and braid statistics.

Proposes a method to construct quantum dimer models from knotted configurations.

Abstract

We consider universal statistical properties of systems that are characterized by phase states with macroscopic degeneracy of the ground state. A possible topological order in such systems is described by non-linear discrete equations. We focus on the discrete equations which take place in the case of generalized exclusion principle statistics. We show that their exact solutions are quantum dimensions of the irreducible representations of certain quantum group. These solutions provide an example of the point where the generalized exclusion principle statistics and braid statistics meet each other. We propose a procedure to construct the quantum dimer models by means of projection of the knotted field configurations that involved braiding features of one-dimensional topology.