Nanoscale engineering of optical strong coupling inside metals

TL;DR

This paper demonstrates nanoscale engineering of cavity-free optical polaritons in metals by coupling interband transitions with surface plasmons, revealing new pathways for designing advanced nanosystems.

Contribution

It introduces a method to engineer strong coupling of interband transitions and surface plasmons in nickel at the nanoscale without the need for optical cavities.

Findings

Surface plasmon and interband transition coupling in nickel was achieved.

Broadening of plasmon linewidth observed in thin films and nanoantennas.

Higher-order plasmon resonances couple to interband transitions, forming multipolar states.

Abstract

Optical polaritons appear when a material excitation strongly couples to the optical mode. Such strong coupling between molecular transitions and optical cavities results in far-reaching opportunities in modifying fundamental properties of chemical matter. More recently an exciting prospect of cavity-free polaritons has emerged by matter sustaining the optical mode with its geometry. Here we show how strong coupling of the interband transition and surface plasmons can be engineered in nickel at the nanoscale to realize cavity-free optical polaritons inside metals. Using electron energy-loss spectroscopy, we demonstrate that in thin films and nanoantennas the propagation and radiation losses result in a broadening of the plasmon linewidth and a transition from strong to weak coupling. Further, higher-order plasmon resonances couple to the interband transition, and the multipolar coupled states acquire the field profile of the plasmon. Our results provide a fundamental understanding of plasmon-interband coupling in metals and establish the base for the design of unforeseen photocatalytic and magneto-optical nanosystems.