Temporal synthesis of optical nonlinearity through synergy of spectrally-tuneable electron and phonon dynamics in a metamaterial

TL;DR

This paper demonstrates a metamaterial-based optical nonlinearity control method that achieves sub-300 fs switching times through spectral tuning and electron-phonon dynamics, enabling advanced ultrafast optical applications.

Contribution

It introduces a novel approach to manipulate optical nonlinearity in metamaterials via spectral control of electron and phonon dynamics, surpassing traditional material response limits.

Findings

Achieved sub-300 fs recovery times in optical constants.

Demonstrated spectral selectivity and polarization sensitivity.

Controlled nonlinear response through Fano interference with acoustic vibrations.

Abstract

Manipulating intensity, phase and polarization of the electromagnetic fields on ultrafast timescales is essential for all-optical switching, optical information processing and development of novel time-variant media. Noble metal based plasmonics has provided numerous platforms for optical switching and control, enabled by strong local field enhancement, artificially engineered dispersion and strong Kerr-type free-electron nonlinearities. However, precise control over switching times and spectrum remains challenging, commonly limited by the relaxation of hot-electron gas on picosecond time scales and the band structure of materials. Here we experimentally demonstrate the strong and tuneable nonlinearity in a metamaterial on a mirror geometry, controlled by the wavelength of excitation, which imprints a specific non-uniform hot-electron population distribution and drives targeted electron and lattice dynamics. The interplay of electromagnetic, electronic and mechanical energy exchange allows us to achieve sub-300~fs timescales in the recovery of optical constants in the selected spectral domains, where the modulation surpasses the limitations imposed by the inherent material response of metamaterial components, owing to emergence of a Fano-type destructive interference with acoustic vibrations of the metamaterial, featured in reflection but not in transmission. The observed effects are highly spectrally selective and sensitive to the polarisation properties of light and the Fabry-Perot modes of the metamaterial, opening a pathway for controlling the switching rates by spectral selection and nanostructure design. The capability to manipulate temporal, spectral and mechanical aspects of light-matter interactions underscores new potential nonlinear applications where polarisation diversity, spectral selectivity and fast modulation are important.