Design Considerations of Gold Nanoantenna Dimers for Plasmomechanical Transduction

TL;DR

This study investigates how the geometry and arrangement of gold nanoantenna dimers influence optical forces generated by plasmonic interactions, with implications for nanomechanical sensing and reconfigurable metamaterials.

Contribution

It provides a detailed analysis of the impact of nanoparticle shape, size, and inter-dimer distance on optical force enhancement using finite element simulations.

Findings

Nanocube dimers exhibit the largest optical forces.

Optical power amplification further increases force magnitude.

Force strength is governed by polarization density affected by geometry and wavelength.

Abstract

Internal optical forces emerging from plasmonic interactions in gold nanodisc, nanocube and nanobar dimers were studied by finite element method. A direct correlation between the electric-field enhancement and optical forces was found by observing largest magnitude of optical forces in nanocube dimers. Moreover, further amplification of optical forces was achieved by employing optical power of the excitation source. The strength of optical forces was observed to be governed by the magnitude of polarisation density on the nanoparticles, which can be varied by modifying the nanoparticle geometry and source wavelength. This study allows us to recognise that nanoparticle geometry along with the inter-dimer distance are the most prominent design considerations for optimising optical forces in plasmonic dimers. The findings facilitate the realisation of all optical modulation in a plasmomechanical nanopillar system, which has promising applications in ultra-sensitive nanomechanical sensing and building reconfigurable metamaterials.