Orbital Frustration and Emergent Flat Bands

Abstract

We expand the concept of frustration in Mott insulators and quantum spin liquids to metals with flat bands. We show that when inter-orbital hopping t2 dominates over intra-orbital hopping t1, in a multiband system with strong spin-orbit coupling λ, electronic states with a narrow bandwidth W t22/λ are formed compared to a bandwidth of order t1 for intra-orbital hopping. We demonstrate the evolution of the electronic structure, Berry phase distributions for time-reversal and inversion breaking cases, and their imprint on the optical absorption, in a tight binding model of d-orbital hopping on a honeycomb lattice. Going beyond quantum Hall effect and twisted bilayer graphene, we provide an alternative mechanism and a richer materials platform for achieving flat bands poised at the brink of instabilities toward novel correlated and fractionalized metallic phases.