A. Chehaidar scite author profile

High index dielectric nanoparticles have been proposed for many different applications. However, widespread utilization in practice also requires large-scale production methods for crystalline silicon nanoparticles, with engineered optical properties in a low-cost manner.Here, we demonstrate a facile, low-cost, and large-scale fabrication method of crystalline silicon colloidal Mie resonators in water, using a blender. The obtained nanoparticles are polydisperse with an almost spherical shape and the diameters controlled in the range 100−200 nm by a centrifugation process. Then the size distribution of silicon nanoparticles enables broad extinction from UV to near-infrared, confirmed by Mie theory when considering the size distribution in the calculations. Thanks to photolithographic and drop-cast deposition techniques to locate the position on a substrate of the colloidal nanoparticles, we experimentally demonstrate that the individual silicon nanoresonators show strong electric and magnetic Mie resonances in the visible range.

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Chemical bonding analysis of a-SiC : H films by Raman spectroscopy

Chehaidar

Carles

Zwick

et al. 1994

Journal of Non-Crystalline Solids

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Tunable enhancement of light absorption and scattering in Si1−xGexnanowires

et al. 2012

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Semiconducting nanowires (NWs) are good candidates for new optoelectronic or photovoltaic devices due to their excellent ability to guide, scatter, or absorb light, from near ultraviolet to near infrared. The existence of morphology-dependent optical resonances opens a promising route to overcome the intrinsic limitations of the constituent material and optimize their interaction with light. We propose a thorough investigation of the optical properties of Si 1−x Ge x alloy nanowires addressing the influence of NW diameter, composition, light polarization, and angle of incidence on their scattering and absorption. Our results clearly show that the Ge composition provides an additional degree of freedom to tailor the optical response of these one-dimensional nano-objects and that resonant enhancement of both absorption and scattering can be obtained in the infrared range at relatively small diameters compared to pure Si nanowires. These results are confirmed by complementary light scattering and Raman spectroscopy experiments using confocal dark field optical microscopy on individual nanowires fabricated by Au-catalyzed vapor-liquid-solid synthesis.

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Photoluminescence enhancement of silicon nanocrystals placed in the near field of a silicon nanowire

et al. 2013

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A. Chehaidar

Large-Scale and Low-Cost Fabrication of Silicon Mie Resonators

Chemical bonding analysis of a-SiC : H films by Raman spectroscopy

Tunable enhancement of light absorption and scattering in Si1−xGexnanowires

Photoluminescence enhancement of silicon nanocrystals placed in the near field of a silicon nanowire

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