Your search keyword '"Fedorenko, Leonid"' showing total 2 results

1. Exciton-Assisted UV Stimulated Emission with Incoherent Feedback in Polydisperse Crystalline ZnO Powder.

Author

Fedorenko, Leonid, Litovchenko, Volodymyr, Naumov, Vadym, Korbutyak, Dmytro, Yukhymchuk, Volodymyr, Gudymenko, Olexander, Dubikovskyi, Olexander, Mimura, Hidenori, and Medvids, Arturs

Subjects

ZINC oxide, POWDERS, COHERENT radiation, NANOPARTICLE size, THIN films, ZINC oxide films

Abstract

A comparative analysis of the features of UV-stimulated emission (SE) of various disordered active materials based on ZnO crystallites for a random laser (RL) was carried out. The superlinear increase in the intensity of the UV photoluminescence (PL) band of polydisperse nano-micro-crystalline (PNMC) ZnO powder at a wavelength of λ = 387 nm and some narrowing of its halfwidth in the range of 20–15 nm with increasing pump intensity indicates random lasing with incoherent feedback (FB). The properties of similar UV PL bands under the same conditions of a thin film containing hexagonal ZnO microdisks, as well as samples of monodisperse ZnO nanopowder with nanoparticle sizes of 100 nm, indicate stimulated radiation with coherent feedback. It is shown that, among the studied materials, PNMC ZnO powder with widely dispersed crystallites ranges in size from 50 nm to several microns, which in turn, consists of nanograins with dimensions of ~25 nm, is the most suitable for creating a random laser with incoherent feedback at room temperature. The dominant factor of UV SE in PNMC ZnO powder is radiation transitions under exciton–exciton scattering conditions. The possible mechanisms of this random emission with the continuous spectrum are discussed. The average optical gain coefficient αg at λ = 387 nm in this RL system is estimated as αg~150 cm−1. [ABSTRACT FROM AUTHOR]

Published

2022

2. Nanostructuring of Continuous Gold Film by Laser Radiation Under Surface Plasmon Polariton Resonance Conditions.

Author

Fedorenko, Leonid, Mamykin, Sergey, Lytvyn, Oksana, Burlachenko, Yulia, and Snopok, Boris

Subjects

*GOLD films, *METALLIC films, *THIN films, *SURFACES (Technology), *IRRADIATION, *PLASMONS (Physics)

Abstract

The physical mechanisms of metallic nanoparticles formation by laser technology were studied. The system air/Au film/glass was irradiated by laser at the conditions of surface plasmon resonance. A surface electromagnetic wave was excited in Kretchmann configuration by the fundamental and second harmonics of the Q-switched YAG/Nd laser with pulse power density close to the threshold of melting. Nanostructuring of Au film was observed only for the second harmonic ( λ = 0.532 μm) irradiation at the surface plasmon polariton resonance (SPR) conditions. Estimations were done using the interference model of the differently directed plasmon polariton waves excited by a surface electromagnetic wave on the metal surface. It was shown that a regular pattern of locally heated spots can be formed in a metallic film by pulsed laser irradiation. The spatial distribution of this pattern is close to the period of interference. The observed effect of laser nanofragmentation is explained by the self-organization of plasmon polariton subsystem in the process of Au nanoparticles formation at high laser intensity levels. These methods open new possibilities for nanostructured surfaces formation utilizing simple self-organization processes. [ABSTRACT FROM AUTHOR]

Published

2011