Boundary-Bulk Interplay in Nonlinear Topological Transport

TL;DR

This paper reveals that boundary modes significantly influence nonlinear transport in topological insulators, with the interplay between boundary and bulk states governing the nonlinear responses, and provides a universal relation to distinguish boundary contributions.

Contribution

It demonstrates the boundary-bulk interplay in nonlinear transport of topological materials and introduces a universal relation to identify boundary mode contributions.

Findings

Nonlinear transport is maximized away from quantized states.

Boundary modes dominate nonlinear responses depending on electrode configuration.

A universal relation distinguishes boundary from bulk contributions.

Abstract

Nonlinear transport has emerged as a powerful approach to probe the quantum geometry of electronic wavefunctions, such as Berry curvature and quantum metric, in topological materials. While nonlinear responses governed by bulk quantum geometry and band topology are well understood, the role of boundary modes (e.g., edge, surface, and hinge states) in nonlinear transport of topological materials remains largely unexplored. In this work, we demonstrate boundary-bulk interplay in nonlinear transport, including second-harmonic Hall and nonreciprocal longitudinal responses, in molecular beam epitaxy-grown magnetic topological insulator heterostructures. We find that the nonlinear transport is maximized when the sample is tuned slightly away from the well-quantized states, including the quantum anomalous Hall and axion insulator states. The sign and amplitude of the nonlinear transport depend on electrode configuration, magnetic order, and carrier type, establishing boundary mode transport as the dominant contributor. These findings, supported by symmetry analysis and nonlinear Landauer-B\"uttiker formalism, demonstrate that nonlinear transport in topological materials is governed by the interplay between boundary and bulk states. We further derive a universal relation between different lead voltages from electrode geometry symmetry, which allows us to distinguish nonlinear boundary transport from bulk contributions. Our work highlights the critical role of electrodes in nonlinear transport, which is absent in nonlinear optics, and establishes boundary modes as a key origin of the giant nonlinear response in nearly bulk-insulating topological materials. This insight opens new opportunities for engineering nonlinear transport through boundary-bulk interplay in future device applications of topological materials.