Obstruction to Broken Symmetries in Topological Flat Bands

TL;DR

This paper explores how topological obstructions prevent certain gapped superconducting and charge orders in half-filled flat bands of 2D topological materials, revealing a new $$ classification related to electron interactions.

Contribution

It generalizes topological obstruction concepts to strongly interacting electrons in flat bands, introducing a $$ classification based on charge Chern numbers.

Findings

Topological obstruction prevents gapped SC and charge orders without topological order.

The $$ classification depends on the Chern number of the flat bands.

Superconductivity and topological order can coexist in a gapped state with specific Chern numbers.

Abstract

Motivated by the abundance of symmetry breaking states in magic-angle twisted bilayer graphene and other two-dimensional materials, we study superconducting (SC) and charge orders in two-dimensional topological flat bands in the strong correlation regime. By relating the half-filled 2D topological flat bands to the surface states of 3D topological insulators in symmetry class AIII, we reveal the topological obstruction to the formation of gapped SC and inter-valley charge orders without intrinsic topological orders, in the presence of the anti-unitary particle-hole symmetry at half filling. This is a generalization of the Li-Haldane arguments for nodal superconductivity to strongly interacting electrons. In contrast to the $\mathbb{Z}$-valued obstruction derived from the non-interacting band topology, the topological obstruction of interacting electrons in half-filled flat bands has a $\mathbb{Z}_{8}$ classification, depending on the charge (valley) Chern number of the superconducting (inter-valley charge) orders. This is demonstrated by an interacting Hamiltonian for half-filled flat bands with a net Chern number $C=4$, where superconductivity and $\mathbb{Z}_2$ topological order coexist in a gapped ground state with particle-hole symmetry.