Nonlinear manifestations of photon acceleration in time-dependent metasurfaces: tunable broadband harmonics generation

TL;DR

This paper demonstrates efficient photon acceleration and tunable high-order harmonic generation using an ultrathin semiconductor metasurface at low intensities, supported by theoretical modeling.

Contribution

It introduces a novel low-intensity nonlinear metasurface that enables broadband harmonic generation through photon acceleration, a phenomenon previously requiring high intensities.

Findings

Observation of third-harmonic generation up to 3.1 times the fundamental frequency

Agreement between experimental results and coupled-mode theory predictions

Potential for broadband nonlinear radiation sources combining upconversion and photon acceleration

Abstract

Time-dependent nonlinear media, such as rapidly generated plasmas produced via laser ionization of gases, can increase the energy of individual laser photons and generate tunable high-order harmonic pulses. This phenomenon, known as photon acceleration, has traditionally required extreme-intensity laser pulses and macroscopic propagation lengths. Here, we report on a novel nonlinear material$-$an ultrathin semiconductor metasurface$-$that exhibits efficient photon acceleration at low intensities. We observe a signature nonlinear manifestation of photon acceleration: third-harmonic generation of near-infrared photons with tunable frequencies reaching up to $\approx3.1\omega$. A simple time-dependent coupled-mode theory, found to be in good agreement with experimental results, is utilized to predict a new path towards nonlinear radiation sources that combine resonant upconversion with broadband operation.