Topological Phases: An Expedition off Lattice

TL;DR

This paper investigates how fluctuating lattice geometries affect topological phases, proposing methods to suppress pathological fluctuations and analyzing the spectral properties of models on such lattices.

Contribution

It introduces three approaches to control geometric fluctuations in lattice models of topological phases and applies Cheeger's theory to analyze their spectral properties.

Findings

Fluctuating geometries can destabilize topological protection.

Proposed suppression methods mitigate pathological fluctuations.

Spectral analysis reveals stability conditions for topological models.

Abstract

Motivated by the goal to give the simplest possible microscopic foundation for a broad class of topological phases, we study quantum mechanical lattice models where the topology of the lattice is one of the dynamical variables. However, a fluctuating geometry can remove the separation between the system size and the range of local interactions, which is important for topological protection and ultimately the stability of a topological phase. In particular, it can open the door to a pathology, which has been studied in the context of quantum gravity and goes by the name of `baby universe', Here we discuss three distinct approaches to suppressing these pathological fluctuations. We complement this discussion by applying Cheeger's theory relating the geometry of manifolds to their vibrational modes to study the spectra of Hamiltonians. In particular, we present a detailed study of the statistical properties of loop gas and string net models on fluctuating lattices, both analytically and numerically.