Tunable plasmons in ultrathin metal films

TL;DR

This paper demonstrates tunable plasmonic resonances in ultrathin gold films down to a few nanometers, revealing new dispersion regimes and electrical tunability, with potential applications in electro-optic devices and sensing.

Contribution

It introduces a novel deposition technique enabling large-area, continuous ultrathin metal films and demonstrates their tunable plasmonic properties at nanometer scales.

Findings

Plasmons observed in 1-3 nm gold films.

Resonance peaks shift by hundreds of nanometers with gating.

Amplitude modulation of tens of percent achieved through low-voltage gating.

Abstract

The physics of electrons, photons, and their plasmonic interactions changes greatly when one or more dimensions are reduced down to the nanometer scale. For example, graphene shows unique electrical, optical, and plasmonic properties, which are tunable through gating or chemical doping. Similarly, ultrathin metal films (UTMFs) down to atomic thickness can possess new quantum optical effects, peculiar dielectric properties, and predicted strong plasmons. However, truly two-dimensional plasmonics in metals has so far elusive because of the difficulty in producing large areas of sufficiently thin continuous films. Thanks to a deposition technique that allows percolation even at 1 nm thickness, we demonstrate plasmons in few-nanometer gold UTMFs, with clear evidence of new dispersion regimes and large electrical tunability. Resonance peaks at 1.5-5 micrometer wavelengths are shifted by hundreds of nanometers and amplitude-modulated by tens of per cent through gating using relatively low voltages. The results suggest ways to use metals in plasmonic applications, such as electro-optic modulation, bio-sensing, and smart windows.