# Spectral focusing of broadband silver electroluminescence in nanoscopic   FRET-LEDs

**Authors:** Robin P. Puchert, Florian Steiner, Gerd Plechinger, Felix Hofmann,, Ines Caspers, Johanna Kirschner, Philipp Nagler, Alexey Chernikov, Christian, Sch\"uller, Tobias Korn, Jan Vogelsang, Sebastian Bange, and John M. Lupton

arXiv: 1702.04243 · 2017-08-02

## TL;DR

This paper demonstrates nanoscopic FRET-LEDs that focus broadband silver electroluminescence into narrow excitonic resonances of monolayer TMDCs, potentially advancing on-chip optical interconnects.

## Contribution

It introduces a novel FRET-LED design that uses energy transfer from silver nanoparticles to TMDC monolayers, focusing broadband EL into narrow spectral features.

## Key findings

- Broadband silver EL is focused into narrow excitonic resonances.
- Photon bunching observed in diffraction-limited hotspots.
- Potential for on-chip optical interconnects using these devices.

## Abstract

Few inventions have shaped the world like the incandescent bulb. While Edison used thermal radiation from ohmically heated conductors, some noble metals exhibit "cold" electroluminescence (EL) in percolation films, tunnel diodes, electromigrated nanoparticle aggregates, optical antennae, or scanning-tunnelling microscopy (STM). The origin of this radiation, which is spectrally broad and depends on applied bias, is controversial given the low radiative yields of electronic transitions. Nanoparticle EL is particularly intriguing since it involves localized surface-plasmon resonances with large dipole moments. Such plasmons enable very efficient non-radiative fluorescence resonance energy transfer (FRET) coupling to proximal resonant dipole transitions. We demonstrate nanoscopic FRET-LEDs which exploit the opposite process, energy transfer from silver nanoparticles to exfoliated monolayers of transition-metal dichalcogenides (TMDCs). In diffraction-limited hotspots showing pronounced photon bunching, broadband silver EL is focused into the narrow excitonic resonance of the atomically thin overlayer. Such devices may offer alternatives to conventional nano-LEDs in on-chip optical interconnects.

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Source: https://tomesphere.com/paper/1702.04243