Complete coupling of focused light to surface polaritons

Surface polaritons display short wavelengths compared to propagating light, thus enabling large spatial concentration and enhancement of electromagnetic energy. However, this wavelength mismatch is generally accompanied by poor light-to-polariton coupling that limits potential applications in areas such as optical sensing and optoelectronics. Here, we address this problem by demonstrating that a small scatterer placed at a suitable distance from a planar surface can produce complete coupling of a focused light beam to surface polaritons. We present rigorous theoretical results for light coupling to plasmons in silver films and graphene, as well as phonon polaritons in hexagonal boron nitride films. We further formulate detailed general prescriptions on the beam profile and particle response that are required to achieve maximum coupling, which we supplement by analytical calculations for dipolar scatterers and finite-size particles. Our results open a practical route to circumvent the long-standing photon-polariton wavelength mismatch problem in nanophotonics. (C) 2021 Optical Society of America under the terms of the OSA Open Access Publishing Agreement

Automated summary

By placing a small scatterer at a suitable distance from a planar surface, complete coupling of a focused light beam to surface polaritons can be achieved, addressing the wavelength mismatch issue. Rigorous theoretical results for light coupling to plasmons in silver films, graphene, and phonon polaritons in hexagonal boron nitride films are presented, along with general prescriptions for achieving maximum coupling through particle response and beam profiles.