Finite-size Topology

TL;DR

This paper explores how finite-size effects in certain dimensions alter the topological classification of systems, leading to hybridized phases characterized by multiple topological invariants, with implications demonstrated in Chern insulators.

Contribution

It introduces a new framework for understanding topological phases in systems finite in some dimensions, revealing hybridization of boundary states and a set of invariants.

Findings

Finite-size boundary states hybridize into new topological phases.

Topological response signatures depend on combined invariants.

Applicable to a broad class of topological systems, exemplified by Chern insulators.

Abstract

We show that topological characterization and classification in $D$-dimensional systems, which are thermodynamically large in only $D-\delta$ dimensions and finite in size in $\delta$ dimensions, is fundamentally different from that of systems thermodynamically large in all $D$-dimensions: as $(D-\delta)$-dimensional topological boundary states permeate into a system's $D$ dimensional bulk with decreasing system size, they hybridize to create novel topological phases characterized by a set of $\delta+1$ topological invariants, ranging from the $D$-dimensional topological invariant to the $(D-\delta)$-dimensional topological invariant. The system exhibits topological response signatures and bulk-boundary correspondences governed by combinations of these topological invariants taking non-trivial values, with lower-dimensional topological invariants characterizing fragmentation of the underlying topological phase of the system thermodynamically large in all $D$-dimensions. We demonstrate this physics for the paradigmatic Chern insulator phase, but show its requirements for realization are satisfied by a much broader set of topological systems.