Battling Retardation and Nonlocality: The Hunt for the Ultimate Plasmonic Cascade Nanolens

Abstract

The plasmonic nanolens was proposed as a deterministic method to achieve high field enhancements and, hence, enable single molecule photonic devices, but experimental results have failed to live up to these expectations, and recent theoretical works have brought its long-assumed advantages into doubt. To explore the limits of cascade field enhancements, we consider possible quantum solutions (“going small”) and use phononic materials at longer wavelengths (“going large”). We find that entering the quantum plasmonic limit to enhance the size ratio between constituent nanoparticles is not a fruitful strategy, as the increased electron-surface scattering decreases the field enhancement by over an order of magnitude. Using larger nanoparticles is limited in metals by retardation, but using localized surface phonon polaritons, which can be excited in polar dielectrics, is an effective strategy due to the lower energy phonon frequency and high quality factor. We compare the nanolens against the more usual dimer...