Giant enhancement and sign inversion of optical Kerr nonlinearity in random high index nanocomposites near Mie resonances

TL;DR

This paper numerically investigates the optical Kerr effect in high-index nanocomposites near Mie resonances, revealing significant enhancement and sign inversion of nonlinearity, which could impact nonlinear optical device development.

Contribution

First numerical analysis of Kerr nonlinearity in high-index nanocomposites near Mie resonances using FDTD simulations, showing enhancement and sign inversion.

Findings

Kerr nonlinearity rises near Mie resonances

Effective Kerr coefficient can exceed bulk material values

Sign of Kerr coefficient inverts near resonances

Abstract

High index dielectric nanoantennas excited at Mie-type resonances have exhibited enormous enhancement of optical nonlinearity. Such nanostructures have been actively studied by researchers in the last years. The present work provides the first numerical analysis study of the optical Kerr effect of nanocomposites consisting of high refractive index (GaP) spheres at the wavelength of 532~nm. This is done by means of three-dimensional finite-difference time-domain (FDTD) simulations. The effective nonlinear refractive index of $0.8$~$\mu$m thick nanocomposites and metasurfaces is evaluated. It is shown that the optical Kerr nonlinearity of the nanocomposites rises by orders in proximity to Mie resonances and may exceed the second-order refractive index of the bulk material. It is revealed that the sign of the effective optical Kerr coefficient is inverted near the Mie resonances. This effect may be of interest in developing nonlinear optical metadevices.