Symmetry Breaking and Nonlinear Electric Transport in van der Waals Nanostructures

The recent development of artificially fabricated van der Waals nanostructures makes it possible to design and control the symmetry of solids and to find novel physical properties and related functionalities. A characteristic physical property reflecting such symmetry breaking is the nonlinear response, which is typically studied as the second harmonic generation of light, although studies have recently expanded to include various transport phenomena. An important aspect of nonlinear transport for modern condensed matter physics is that it is not only a unique functionality of noncentrosymmetric systems but also an emergent property reflecting underlying physics such as spin-orbit interaction, superconductivity, magnetism, and band geometry/topology. In this article, we review the nonlinear electrical transport in noncentrosymmetric van der Waals nanostructures obtained by exfoliation, nano-structure fabrication, or the application of an electric field, in particular, nonreciprocal transport resulting from inversion symmetry breaking and the bulk photovoltaic effect in nanomaterials without conventional p-n junctions.

Automated summary

Recent advances in artificially fabricated van der Waals nanostructures have allowed for the design and control of solid symmetry, leading to the discovery of new physical properties. Nonlinear transport in condensed matter physics plays a critical role, showcasing unique functionalities of noncentrosymmetric systems and reflecting underlying physics processes.