# Unveiling the Radiative Local Density of Optical States of a Plasmonic   Nanocavity by STM Luminescence and Spectroscopy

**Authors:** Alberto Mart\'in-Jim\'enez, Antonio I. Fern\'andez-Dom\'inguez, Koen, Lauwaet, Daniel Granados, Rodolfo Miranda, Francisco J. Garc\'ia-Vidal and, Roberto Otero

arXiv: 1907.07939 · 2020-03-18

## TL;DR

This paper introduces an experimental method to isolate radiative plasmonic modes in metallic nanocavities using STM luminescence and spectroscopy, enabling detailed analysis of plasmonic mode shifts and Purcell enhancement.

## Contribution

The study presents a novel procedure to remove electronic-structure influences from STM luminescence spectra, allowing precise characterization of plasmonic modes and their shifts at atomic-scale gaps.

## Key findings

- Successfully disentangled radiative modes from electronic effects.
- Demonstrated meV shifts in plasmonic modes with gap size changes.
- Accessed frequency-dependent Purcell enhancement for nanocavities.

## Abstract

Disentangling the contributions of radiative and non-radiative localized plasmonic modes from the photonic density of states of metallic nanocavities between atomically-sharp tips and flat substrates remains an experimental challenge nowadays. Electroluminescence due to tunnelling through the tip-substrate gap allows discerning solely the excitation of radiative modes, but this information is inherently convolved with that of the electronic structure of the system. In this work we present a fully experimental procedure to eliminate the electronic-structure factors from the scanning tunnelling microscope luminescence spectra by confronting them with spectroscopic information extracted from elastic current measurements. Comparison against electromagnetic calculations demonstrates that this procedure allows characterizing the meV shifts experienced by the dipolar and quadrupolar plasmonic modes supported by the nanocavity under atomic-scale gap size changes. Our method, thus, gives us access to the frequency-dependent radiative Purcell enhancement that a microscopic light emitter would undergo when placed at the nanocavity.

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Source: https://tomesphere.com/paper/1907.07939