Litcius/Paper detail

Quantum oscillations in the magnetization and density of states of insulators

Animesh Panda, Sumilan Banerjee, Mohit Randeria

2022Proceedings of the National Academy of Sciences19 citationsDOIOpen Access PDF

Abstract

The observation of [Formula: see text]-periodic behavior in Kondo insulators and semiconductor quantum wells challenges the conventional wisdom that quantum oscillations (QOs) necessarily arise from Fermi surfaces in metals. We revisit recently proposed theories for this phenomenon, focusing on a minimal model of an insulator with a hybridization gap between two opposite-parity light and heavy mass bands with an inverted band structure. We show that there are characteristic differences between the QO frequencies in the magnetization and the low-energy density of states (LE-DOS) of these insulators, in marked contrast to metals where all observables exhibit oscillations at the same frequency. The magnetization oscillations arising from occupied Landau levels occur at the same frequency that would exist in the unhybridized case. The LE-DOS oscillations in a disorder-free system are dominated by gap-edge states and exhibit a beat pattern between two distinct frequencies at low temperature. Disorder-induced in-gap states lead to an additional contribution to the DOS at the unhybridized frequency. The temperature dependence of the amplitude and phase of the magnetization and DOS oscillations are also qualitatively different and show marked deviations from the Lifshitz-Kosevich form well known in metals. We also compute transport to ensure that we are probing a regime with insulating upturns in the direct current (DC) resistivity.

Topics & Concepts

Condensed matter physicsPhysicsMagnetizationQuantum oscillationsDensity of statesObservableQuantumAmplitudeMetal–insulator transitionElectrical resistivity and conductivityFermi surfaceQuantum mechanicsMagnetic fieldSuperconductivityQuantum and electron transport phenomenaOrganic and Molecular Conductors ResearchPhysics of Superconductivity and Magnetism