All-Optical Generation and Detection of Coherent Acoustic Vibrations in Single Gallium Phosphide Nanoantennas Probed Near the Anapole Excitation

Nanostructured high-index dielectrics have shown great promise as low-loss photonic platforms for wavefront control and enhancing optical nonlinearities. However, their potential as optomechanical resonators has remained unexplored. In this work, we investigate the generation and detection of cohere...

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Veröffentlicht in:	arXiv.org 2024-10
Hauptverfasser:	Boggiano, Hilario D, Roqueiro, Nicolas A, Zhang, Haizhong, Krivitsky, Leonid, Cortes, Emiliano, Maier, Stefan A, Bragas, Andrea V, Kuznetsov, Arseniy, Grinblat, Gustavo
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Schlagworte:	Acoustic waves Acoustics Dielectrics Energy gap Gallium phosphides Nanoantennas Nanorods Photonic crystals Resonators Substrates Wave front control Wave fronts
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description	Nanostructured high-index dielectrics have shown great promise as low-loss photonic platforms for wavefront control and enhancing optical nonlinearities. However, their potential as optomechanical resonators has remained unexplored. In this work, we investigate the generation and detection of coherent acoustic phonons in individual crystalline gallium phosphide nanodisks on silica in a pump-probe configuration. By pumping the dielectric above its bandgap energy and probing over its transparent region, we observe the radial breathing mode of the disk with an oscillation frequency around 10 GHz. We analyze the performance of nanoantennas of various sizes in the 300-600 nm diameter range at fixed 125 nm height and find that the detection efficiency is maximum near the fundamental anapole state, in agreement with numerical simulations. By comparing with reference gold nanodisk and nanorod plasmonic resonators, we find that the dielectric nanoantennas display a modulation amplitude up to ~5 times larger. We further demonstrate the launching of acoustic waves through the underlaying substrate and the mechanical coupling between two nanostructures placed 3 {\mu}m apart, laying the basis for photonic-phononic signal processing using dielectric nanoantennas.
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subjects	Acoustic waves Acoustics Dielectrics Energy gap Gallium phosphides Nanoantennas Nanorods Photonic crystals Resonators Substrates Wave front control Wave fronts
title	All-Optical Generation and Detection of Coherent Acoustic Vibrations in Single Gallium Phosphide Nanoantennas Probed Near the Anapole Excitation
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