Nonlinear Landauer formula: Nonlinear response theory of disordered and topological materials

TL;DR

This paper extends the Landauer formula to nonlinear regimes, revealing how nonlinear conductance relates to energy derivatives of transmission, and explores its implications in disordered, topological, and quantum materials.

Contribution

It develops a scattering theory for nonlinear response, connecting nonlinear conductance to energy derivatives and uncovering phenomena in disordered, topological, and quantum systems.

Findings

Universal nonlinear conductance behavior in disordered chains.

Large singular nonlinear conductance for zero modes, including Majorana modes.

Critical nonlinear response near mobility edges and in graphene.

Abstract

The Landauer formula provides a general scattering formulation of electrical conduction. Despite its utility, it has been mainly applied to the linear-response regime, and a scattering theory of nonlinear response has yet to be fully developed. Here, we extend the Landauer formula to the nonlinear-response regime. We show that while the linear conductance is directly related to the transmission probability, the nonlinear conductance is given by its derivatives with respect to energy. This sensitivity to the energy derivatives is shown to produce unique nonlinear transport phenomena of mesoscopic systems including disordered and topological materials. By way of illustration, we investigate nonlinear conductance of disordered chains and identify their universal behavior according to symmetry. In particular, we find large singular nonlinear conductance for zero modes, including Majorana zero modes in topological superconductors. We also show the critical behavior of nonlinear response around the mobility edges due to the Anderson transitions. Moreover, we study nonlinear response of graphene as a prime example of topological materials featuring quantum anomaly. Furthermore, considering the geometry of electronic wave functions, we develop a scattering theory of the nonlinear Hall effect. We establish a new connection between the nonlinear Hall response and the nonequilibrium quantum fluctuations. We also discuss the influence of disorder and Anderson localization on the nonlinear Hall effect. Our work opens a new avenue in quantum physics beyond the linear-response regime.