Design and Analysis of Surface Plasmon Enhanced Electric Field in Al, Ag and Au Nanoparticle Dimers for UV-Visible Plasmonics

TL;DR

This paper investigates how Al, Ag, and Au nanoparticle dimers enhance electric fields via surface plasmon resonances, with implications for UV-Visible applications like sensing and photothermal therapy.

Contribution

It introduces a spectral expansion approach to analyze electric field enhancement in nanoparticle dimers and assesses their suitability for UV-Visible plasmonic applications.

Findings

Dimer arrangements provide greater field enhancement than isolated nanoparticles.

Particle size, medium, and separation significantly influence spectral tuning.

Designed dimers are suitable for UV-Visible spectral applications.

Abstract

It is now well established that, due to excitation of localized surface plasmon resonances in plasmonic nanosystems, the electric field from an external irradiation source is greatly amplified in their vicinity. Surface plasmon mediated electric field amplification near plasmonic nanosystems is of vital importance for; light absorption enhancement of solar cells, molecular detection using surface enhanced Raman spectroscopy, proximity measurement of biological macromolecules such as proteins, lipids and nucleic acids using plasmon enhanced FRET, cancer therapy using photothermal effects, just to name only a few applications. Present work formulates Bergman-Milton multipole spectral expansion approach for investigating surface plasmon mediated electric field amplification in the dimer arrangement of Al, Ag and Au nanoparticles. In comparison to an isolated spherical shaped nanoparticle, their aggregate provide greater field enhancement, wider spectral tuning, and multiple resonant features. In view of the superior plasmonic characteristics of dimer configuration, a systematic investigation of electric field enhancement is done and their suitability for UV-Visible applications is assessed. The role of particle size, embedding medium and interparticle separation in field amplification and wavelength tuning is quantified. Moreover, plasmonic nanoparticle dimer designs for UV-Visible spectral window are presented.