Future technologies underpinning high-performance optical communications, ultrafast
computations and compact biosensing will rely on densely packed reconfigurable optical …

Nanophotonics underpins the future technologies for creating reconfigurable optical circuitry
for high-performing optical devices, ultrafast computers, and very compact efficient …

Rapid progress in photonics and its applications underpins the development of highly
efficient optical devices for communications, ultrafast computations, compact biosensing …

Subwavelength optical resonators made of high-index dielectric materials provide efficient
ways to manipulate light at the nanoscale through mode interferences and enhancement of …

All-dielectric resonant nanophotonics is a rapidly developing research field driven by its
exceptional applications for creating low-loss nanoscale metadevices. The tight confinement …

Benefited from the well-known Mie resonance, a plethora of physical phenomena and
applications are attracting attention in current research on dielectric-based nanophotonics …

Recent progress in nanoscale optical physics is associated with the development of a new
branch of nanophotonics exploring strong Mie resonances in dielectric nanoparticles with a …

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 …

In recent years, high-index dielectric nanoantennas supporting Mie resonances have
emerged as a promising platform to create low-loss nanophotonic devices. The multipolar …

Recent progress in nanoscale optics is driven by the physics of electric and magnetic
resonances supported by high-index dielectric nanoparticles. Here, we exploit optical bound …