Interplay of quantum and real-space geometry in the anomalous Landau levels of singular flat bands

Abstract

Quantum geometry of electronic state in momentum space, distinct from real-space structural geometry, has attracted increasing interest to shed light on understanding quantum phenomena. An interesting recent study [Nature 584, 59-63 (2020)] has numerically solved a 2-band effective Hamiltonian to show the anomalous Landau level (ALL) spreading of a singular flat band (SFB), such as hosted in a kagome lattice, in relation to the maximal quantum distance d of the SFB, (d), which enables a direct measure of quantum geometry. Here, we investigate the ALLs of SFB by studying both the 2-band Hamiltonian and a diatomic kagome lattice hosting two SFBs mirrored by particle-hole symmetry. We derive an exact analytical solution of the 2-band Hamiltonian to show there are two branches of (d). Strikingly, for the diatomic kagome lattice, depends on not only d but also r, the real-space diatomic distance. As r increases, shrinks toward zero while d remains intact, which can be intuitively understood from the magnetic-field-induced disruption of destructive interference of the SFB compact localized states. Based on semiclassical theory, we derive rigorously the dependence of on r that originates from the tuning of the non-Abelian orbital moment of the two SFBs by real-space geometry.