All-dielectric metamaterials and metasurfaces have been demonstrated as ideal platforms to
manipulate electromagnetic waves and enhance light–matter interaction. Analogous to …

Wireless power transfer—the transmission of electromagnetic energy without physical
connectors such as wires or waveguides—typically exploits electromagnetic field control …

Electromagnetic anapole mode is a nonradiative state of light originating from the
deconstructive interference of radiation of the oscillating electric and toroidal dipole …

Mie-resonant metaphotonics is a rapidly develo** field that employs the physics of Mie
resonances to control light at the nanoscale. Mie resonances are excited in high-refractive …

Future technologies underpinning multifunctional physical and chemical systems and
compact biological sensors will rely on densely packed transformative and tunable circuitry …

We introduce a general concept and consider a characteristic approach to obtain the narrow-
band suppression of total electromagnetic scattering independent of the irradiation …

We develop a theoretical approach that makes it possible to analyze the role of multipole
contributions in the scattering spectra of arbitrarily shaped magnetic particles with the …

Anapole states associated with the destructive interference between dipole and toroidal
moments result in suppressed scattering accompanied by strongly enhanced near fields. In …

The rapid development of optical technologies, such as optical manipulation, data
processing, sensing, microscopy, and communications, necessitates new degrees of …

The optical anapole state resulting from interference of the electric and toroidal moments is
of much interest due to its nonradiating nature. Interference of optical modes supported by a …