Iran F. da Silva scite author profile

In recent years, there has been dramatic progress in the photonics field in disordered media, ranging from applications in solar collectors, photocatalyzers, random lasing, and other novel photonic functions, to investigations into fundamental topics, such as light confinement and other phenomena involving photon interactions. This paper reports several pieces of experimental evidence of localization transition in a strongly disordered scattering medium composed of a colloidal suspension of core-shell nanoparticles (TiO2@silica) in ethanol solution. We demonstrate the crossover from a diffusive transport to a localization transition regime as the nanoparticle concentration is increased, and that an enhanced absorption effect arises at localization transition.

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Random Lasing at Localization Transition in a Colloidal Suspension (TiO₂@Silica)

Jiménez‐Villar

Silva²,

Mestre

et al. 2017

ACS Omega

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Anderson localization of light and random lasing in this critical regime is an open research frontier, which besides being a basic research topic could also lead to important applications. This article investigates the random laser action at the localization transition in a strongly disordered scattering medium composed of a colloidal suspension of core–shell nanoparticles (TiO 2 @Silica) in ethanol solution of Rhodamine 6G. The classical superfluorescence band of the random laser was measured separately by collecting the emission at the back of the samples, showing a linear dependence with pumping fluence without gain depletion. However, frontal collection showed saturation of the absorption and emission. Narrow peaks of approximately equal intensity are observed on top of the classical superfluorescence band, indicating suppression of the interaction between the peaks modes. The linewidth of these peaks is lower than that of the passive modes of the scattering medium. A method called fraction of absorbed pumping allowed us to infer that this peak’s mode (localized modes) is confined to a shallow region near the input-pumping border.

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Core-shell TiO 2 @Silica nanoparticles for light confinement

Jiménez‐Villar

Mestre

Martins

et al. 2017

Materials Today: Proceedings

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Iran F. da Silva

Anderson localization of light in a colloidal suspension (TiO₂@silica)

Random Lasing at Localization Transition in a Colloidal Suspension (TiO₂@Silica)

Core-shell TiO 2 @Silica nanoparticles for light confinement

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About

Iran F. da Silva

Anderson localization of light in a colloidal suspension (TiO2@silica)

Random Lasing at Localization Transition in a Colloidal Suspension (TiO2@Silica)

Core-shell TiO 2 @Silica nanoparticles for light confinement

Contact Info

Product

Resources

About

Anderson localization of light in a colloidal suspension (TiO₂@silica)

Random Lasing at Localization Transition in a Colloidal Suspension (TiO₂@Silica)