Plasmonics in Atomically-Thin Crystalline Silver Films.

Light-matter interaction at the atomic scale rules fundamental phenomena such as photoemission and lasing, while enabling basic everyday technologies, including photovoltaics and optical communications. In this context, plasmons --the collective electron oscillations in conducting materials-- are important because they allow manipulating optical fields at the nanoscale. The advent of graphene and other two-dimensional crystals has pushed plasmons down to genuinely atomic dimensions, displaying unique properties like an unparalleled electrical tunability. However, plasmons in these materials are either too broad or lying at low frequencies, well below the technologically relevant near-infrared regime. Here we demonstrate sharp near-infrared plasmons in lithographically-patterned wafer-scale atomically-thin silver crystalline films. Our measured optical spectra reveal extraordinarily narrow plasmons, further supported by an unprecedentedly low sheet resistance in few-atomic-layer silver films. The achieved crystal quality and plasmon narrowness exceed all expectations, despite the addition of a thin passivating dielectric, which renders our samples resilient to ambient conditions. The observation of narrow plasmons in atomically thin silver opens a new avenue in plasmonics, as their strong spatial confinement holds great potential for electro-optical modulation and optical sensing applications.