Title :
Steady-state photorefractive gratings in LiNbO3 for strong light modulation depths
Author :
Serrano, E. ; López, V. ; Carrascosa, M. ; Agulló-López, F.
Author_Institution :
Inst. de Ingenieria del Conocimiento, Univ. Autonoma de Madrid, Spain
fDate :
4/1/1994 12:00:00 AM
Abstract :
The steady-state field gratings recorded in photovoltaic photorefractive materials have been investigated theoretically for high modulation´s depths of the light intensity pattern (up to modulation depth m≈1). Several numerical methods have been used to deal with this strongly nonlinear regime and their capability critically evaluated. The number of harmonics contributing to the field gratings increases very strongly with m above m≳0.8, leading to a strong localization of the fringes. The dependence of grating amplitude has been found to be superlinear on m. The role of the k vector, impurity concentration, and oxidation/reduction state on the holographic recording efficiency has also been analyzed
Keywords :
holographic gratings; impurities; lithium compounds; numerical analysis; optical modulation; photorefractive materials; photovoltaic effects; LiNbO3; fringes; grating amplitude; harmonics; holographic recording efficiency; impurity concentration; k vector; light intensity pattern; numerical methods; oxidation/reduction state; photovoltaic photorefractive materials; steady-state field gratings; steady-state photorefractive gratings; strong light modulation depths; strong localization; strongly nonlinear regime; superlinear; Gratings; Impurities; Intensity modulation; Optical modulation; Oxidation; Photorefractive effect; Photorefractive materials; Photovoltaic systems; Solar power generation; Steady-state;
Journal_Title :
Quantum Electronics, IEEE Journal of
