Abstract

We present a theory of quantum oscillations in insulators that are particle-hole symmetric and nontopological but with arbitrary band dispersion, at both zero and nonzero temperature. At temperatures $T$ less than or comparable to the gap, the dependence of oscillations on $T$ is markedly different from that in metals and depends crucially on the position of the chemical potential $\ensuremath{\mu}$ in the gap. If $\ensuremath{\mu}$ is in the middle of the gap, oscillations do not change with $T$; however, if $\ensuremath{\mu}$ is asymmetrically positioned in the gap, surprisingly, oscillations go to zero at a critical value of the inverse field determined by $T$ and $\ensuremath{\mu}$ and then change their phase by $\ensuremath{\pi}$ and grow again. Additionally, the temperature dependence is different for quantities derived from the grand canonical potential, such as magnetization and susceptibility, and those derived from the density of states, such as resistivity. However, the nontrivial features arising from asymmetric $\ensuremath{\mu}$ are present in both.