Litcius/Paper detail

Multipole engineering by displacement resonance: a new degree of freedom of Mie resonance

Yu‐Lung Tang, Te-Hsin Yen, Kentaro Nishida, Chien-Hsuan Li, Yu‐Chieh Chen, Tianyue Zhang, Chi-Kang Pai, Kuo‐Ping Chen, Xiangping Li, Junichi Takahara, Shi‐Wei Chu

2023Nature Communications14 citationsDOIOpen Access PDF

Abstract

The canonical studies on Mie scattering unravel strong electric/magnetic optical responses in nanostructures, laying foundation for emerging meta-photonic applications. Conventionally, the morphology-sensitive resonances hinge on the normalized frequency, i.e. particle size over wavelength, but non-paraxial incidence symmetry is overlooked. Here, through confocal reflection microscopy with a tight focus scanning over silicon nanostructures, the scattering point spread functions unveil distinctive spatial patterns featuring that linear scattering efficiency is maximal when the focus is misaligned. The underlying physical mechanism is the excitation of higher-order multipolar modes, not accessible by plane wave irradiation, via displacement resonance, which showcases a significant reduction of nonlinear response threshold, sign flip in all-optical switching, and spatial resolution enhancement. Our result fundamentally extends the century-old light scattering theory, and suggests new dimensions to tailor Mie resonances.

Topics & Concepts

Mie scatteringPhysicsScatteringOpticsMultipole expansionResonance (particle physics)Paraxial approximationLight scatteringAtomic physicsQuantum mechanicsBeam (structure)Plasmonic and Surface Plasmon ResearchPhotonic and Optical DevicesNear-Field Optical Microscopy