The concentration and manipulation of light in the nanoscale range are fundamental to
nanophotonic research. Plasmonic nanoparticles can localize electromagnetic waves within …

All-dielectric nanophotonics is an exciting and rapidly developing area of nano-optics that
utilizes the resonant behavior of high-index low-loss dielectric nanoparticles to enhance …

This review overviews the state of the art of research into high-index dielectric
nanoresonators and their use in functional photonic nanostructures at optical frequencies …

BACKGROUND Nanoscale optics is usually associated with plasmonic structures made of
metals such as gold or silver. However, plasmonics suffers from high losses of metals …

The quest for enhancing light–matter interactions at the nanoscale has led scientists to
nanophotonic systems that support the smallest possible modes, which are currently …

All-dielectric nanostructures have aroused strong interest because of their potential to trap
light at subwavelength scales and to yield strong internal electric or magnetic field …

Material losses in metals are a central bottleneck in plasmonics for many applications. Here
we propose and theoretically demonstrate that metal losses can be successfully mitigated …

The future of ultra-fast optical communication systems is inevitably connected with progress
in optical circuits and nanoantennas. One of the key points of this progress is the creation of …

Enhancing the light‐matter interactions is important for many different applications like
sensing, surface enhanced spectroscopies, solar energy harvesting, and for quantum effects …

High-index dielectric nanostructures have recently become prominent forefront alternatives
for manipulating light at the nanoscale. Their electric and magnetic resonances with …