18 May 2015 Modeling of self-diffraction from the induced aperture in colloidal quantum dots
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Abstract
Modeling of self-diffraction pattern formation from the induced diaphragm, arising in the case of the transparency channel saturation by one-photon resonant non-stationary excitation of the basic exciton transition in colloidal quantum dots (QDs) is realized. The simulation results allow us to obtain the reference image of self-diffraction pattern and dependence of the intensity transverse distribution of the output beam from the intensity of the excitation beam, forming a transparency channel. A powerful laser pulse creates a transparency channel, so that it self-diffracts on the induced diaphragm. The possibility to apply the obtained simulation results for intensity estimation of the laser radiation and for the possible application in the technique (nonlinear-optical limiters of intense laser radiation in the visible and nearinfrared region, optical switches) are discussed.
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K. Ezhova, A. Smirnov, "Modeling of self-diffraction from the induced aperture in colloidal quantum dots", Proc. SPIE 9503, Nonlinear Optics and Applications IX, 950315 (18 May 2015); doi: 10.1117/12.2178661; https://doi.org/10.1117/12.2178661
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