A combination of electron and ion beam lithographies has been applied to fabricate patterns of plasmonic nanoparticles having tailored optical functions: they create hot-spots at predefined locations on the nanoparticle at specific wavelengths and polarizations of the incident light field. Direct inscribing of complex chiral patterns into uniform nano-disks of sub-wavelength dimensions, over extensive 20 by 20 mu m2 areas, is achieved with high fidelity and efficiency; typical groove widths are in 10-30 nm range. Such patterns can perform optical manipulation functions like nano-tweezing and chiral sorting. Fabrication procedures can be optimized to pattern thin 0.1-2.5 mu m-thick membranes with chiral nanoparticles having sub15 nm grooves. Peculiarities of optical force and torque calculations using finite difference time domain method are presented.
Chiral plasmonic nano structures : experimental and numerical tools / Gervinskas, Gediminas; Rosa, Lorenzo; Brasselet, Etienne; Juodkazis, Saulius. - 8613:(2013), pp. 861304.1-861304.13. (Intervento presentato al convegno Advanced Fabrication Technologies for Micro/Nano Optics and Photonics VI tenutosi a San Francisco, California, United States nel 2-7 February 2013) [10.1117/12.2002281].
Chiral plasmonic nano structures : experimental and numerical tools
ROSA, Lorenzo;
2013
Abstract
A combination of electron and ion beam lithographies has been applied to fabricate patterns of plasmonic nanoparticles having tailored optical functions: they create hot-spots at predefined locations on the nanoparticle at specific wavelengths and polarizations of the incident light field. Direct inscribing of complex chiral patterns into uniform nano-disks of sub-wavelength dimensions, over extensive 20 by 20 mu m2 areas, is achieved with high fidelity and efficiency; typical groove widths are in 10-30 nm range. Such patterns can perform optical manipulation functions like nano-tweezing and chiral sorting. Fabrication procedures can be optimized to pattern thin 0.1-2.5 mu m-thick membranes with chiral nanoparticles having sub15 nm grooves. Peculiarities of optical force and torque calculations using finite difference time domain method are presented.
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