Anomalous Lorenz number in massive and tilted Dirac systems

Abstract

We analytically calculate the anomalous transverse electric and thermal currents in massive and tilted Dirac systems, using β -borophene as a representative material, and report on conditions under which the corresponding Lorenz number (Lan) deviates from its classically accepted value (L0). The deviations in the high-temperature regime are shown to be an outcome of the quantitative difference in the respective kinetic transport expressions for electric (σ) and thermal () conductivity, and are further weighted through a convolution integral with a non-linearly energy-dependent Berry curvature that naturally arises in a Dirac material. In addition, the tilt and anisotropy of the Dirac system that are amenable to change via external stimulus are found to quantitatively influence Lan . The reported deviations from L0 hold practical utility inasmuch as they allow an independent tuning of σ and , useful in optimizing the output of thermoelectric devices.