3D nonlinear optical metamaterials from twisted 2D van der Waals interfaces

TL;DR

This paper reports the creation of 3D nonlinear optical metamaterials by precisely twisting 2D van der Waals interfaces, enabling new nonlinear responses and enhanced susceptibilities through atomic-scale control.

Contribution

It introduces a novel method of engineering nonlinear optical properties by twisting 2D van der Waals layers to form 3D metamaterials with unique symmetries and enhanced nonlinear responses.

Findings

New nonlinear crystals with pseudo screw symmetries created from twisted WS2 layers.

Enhanced nonlinear susceptibility achieved by controlling interface number and excitation wavelength.

Scalable approach from nanometer-thick units to bulk materials.

Abstract

To enable new nonlinear responses, metamaterials are created by organizing structural units (meta-atoms) which are typically on the scale of about a hundred nanometers. However, truly altering atomic symmetry and enabling new nonlinear responses requires control at the atomic-scale, down to a few angstroms. Here we report the discovery of 3D nonlinear optical metamaterials realized by the precise control and twist of individual 2D van der Waals interfaces. Specifically, new nonlinear crystals are achieved by adding pseudo screw symmetries to a multiple of 4-layer WS2 stacks (e.g. 4-layer, 8-layer, etc). The nonlinear susceptibility of the resulting 3D crystal is fundamentally different from natural WS2. Furthermore, we show that the magnitude of the newly enabled nonlinearity is enhanced by controlling the number of interfaces and the excitation wavelength. Our findings suggest a new approach to redesigning intrinsic nonlinearity in artificial atomic configurations, scalable from a few nanometer-thick unit cells to bulk materials.