HomeNanotechnologyNANOMATERIALSReconfigurable silicon nanoantennas controlled by vectorial light field

Reconfigurable silicon nanoantennas controlled by vectorial light field

A new publication from Opto-Electronic Advances considers reconfigurable silicon nanoantennas controlled by vectorial light field. High-index dielectric particles can be induced with intense electric and magnetic multipole resonance under visible range. The interference between electric and magnetic multipole in particles will bring many novel optical properties.

Since silicon is the most commonly used material for semiconductor devices with a high refractive index. The use of micro-nano silicon structures as all-dielectric optical nano-antennas provides a high-quality platform for optical field modulation and interaction between light and matter at the nanoscale.

All-dielectric optical nanostructures excited by a specific optical field will exhibit a novel electromagnetic mode, anapole mode. This mode induced by destructive interference between electric dipole and toroidal dipolar can realize a radiationless mode in which far-field scattering is completely disappears. The optical scattering of a nanoparticle under the excitation of a plane wave is usually determined by its predominant electromagnetic multipole moment.

Such a predominant multipole moment can even decide the electric or magnetic nature of the scattering in all-dielectric photonics. It is generally perceived that sophisticated manipulation of electromagnetic multipolar moments of all orders to realize superposition of vanished moment strengths at the same wavelength are necessary to achieve the anapole condition.

Professor Li Xiangping’s research group discovered that sophisticated tailoring of electromagnetic multipolar moments in nanoparticles is unnecessary for the excitation of the anapole condition. This article reports the theoretical and experimental demonstration of radiationless optical anapole hidden in a resonant state of a-Si nanoparticle utilizing a tightly focused radially polarized beam. The results demonstrate the possibility for the realization of high contrast reconfigurable optical scattering.

The demonstrated mechanism resembles a new and unparalleled way to tailor the optical properties of meta-structures. The authors anticipate that this discovery could pave the way for the advanced manipulation of optical signals in nanophotonics.


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