Title :
Large modulation effects in photorefractive crystals
Author :
Swinburne, G.A. ; Hall, T.J. ; Powell, A.K.
Author_Institution :
King´´s College London, UK
Abstract :
A numerical solution to the band transport equations is presented, which is quite general, and predicts the behaviour of photorefractive materials in the saturation limit with a moving grating. The band transport equations are solved by a secular perturbation method, where the perturbation parameter is the fundamental component of the induced space charge field. In this manner, one can predict the form of the space charge field and the charge density distribution at various depths of modulation. The effects of applying an AC field with a square waveform to a static grating are considered and it is shown that there is an upper limit to the degree of enhancement obtainable at any particular depth of modulation
Keywords :
diffraction gratings; electro-optical effects; numerical methods; optical modulation; perturbation techniques; photorefractive effect; space charge; AC field; band transport equations; charge density distribution; digital simulation; induced space charge field; moving grating; numerical solution; optical modulation; perturbation parameter; photorefractive crystals; saturation limit; secular perturbation method; square waveform; static grating;
Conference_Titel :
Holographic Systems, Components and Applications, 1989., Second International Conference on
Conference_Location :
Bath
