Correlated Fragile Topology: a Parton Approach

TL;DR

This paper introduces a general parton approach to construct and understand fragile topological insulators in strongly correlated systems, revealing emergent negative charges and short-range entangled states.

Contribution

It proposes a novel parton construction framework for correlation-enabled fragile topological insulators, extending the concept beyond free fermion systems.

Findings

Parton construction naturally produces emergent negative charges.

Fragile phases can be viewed as FTIs of charge-2, spin singlet bosonic pairs.

Includes examples of correlated FTIs and featureless Mott insulators.

Abstract

A fragile topological insulator (FTI) can be viewed as an almost-atomic insulator, with emergent negative charges localized at certain real space points, even though the underlying lattice Hilbert space contains only positively charged states. Fragile topology in free fermion systems has been fruitfully studied using modern topological band theory. However, the concept is well defined even for strongly correlated systems, and fragile states that cannot be realized within free fermion band theory exist abundantly. In this work we propose a rather general parton construction for such correlation-enabled FTIs. In our parton construction the associated gauge symmetries are completely Higgsed, resulting in only short-range entangled states. The effective negative charges in the FTIs emerge naturally as the remnants of negatively charged partons. For spinful electrons with $SU(2)$ spin-rotation symmetry, the fragile phases can be viewed as FTIs of charge-$2$, spin singlet bosonic Cooper pairs. We discuss a few examples of correlated FTIs for both spinless and spinful fermions, including some "featureless Mott insulators" on the honeycomb lattice previously discussed in the literature.