does not require an activation energy but it is certainly characterized by dissipation associated with the viscosity at the boundary between the crystalline domains and the amorphous matrix. A detailed description of this process goes well beyond the scope of this introductory communication.The recording speed of the holograms in our samples is of the order of tens of seconds, much slower than in the photorefractive composites with the smallest response times, [18,19] and this represents the main limit of our materials. Improvement in response time may require tighter control of the shape of the dispersed domains and of their surface dissipative properties. An increase in the holographic writing time was also observed as the AZPON content was lowered. This can be attributed to an increase in the surface/volume ratio of smaller domains, corresponding to an increased effect of the viscosity torques relative to the reorienting field torques. The stability towards further phase separation, corresponding to an increase in domain size beyond the limit of scattering in the visible, is relatively good, with little or no decrease of efficiency over a period of several months. An increase in the scattering is however observed after a 5±10 months period at room temperature, although the original performance is regained after a heating±cooling cycle during which phase separation is repeated. An improvement in the stability of the nanodispersions can, in principle, be obtained through well established techniques (vulcanization, reinforcement, etc.) of polymer stabilization. In summary, our data indicate that, at a given applied electric field, controlled phase separation can increase the orientational contribution to the dynamic range by orders of magnitude. As the improvement in performance that we describe here can in principle be obtained in most photoconductive composites, this method considerably broadens the range of potentially useful photorefractive materials for applications ranging from holographic storage to medical imaging.
ExperimentalSamples consisted of thin amorphous films between two indium tin oxidecoated conducting glasses. They were obtained by mixing the required amounts of substances in chloroform and evaporating the solvent. Empty cells containing only glass spacers to control the thickness were prepared, placed on a hot plate, filled by capillary action, and cooled rapidly to room temperature. Alternatively, for solutions with higher viscosity, the hot melt was sandwiched between two hot glasses and then rapidly cooled.Light transmission was measured for a p-polarized laser beam at 633 nm, incident at a 60 angle with respect to the sample normal.Diffraction efficiency was measured by degenerate four-wave mixing experiments, carried out by overlapping two writing beams on a circular area of the sample with a 1 mm diameter. Writing beams had equal intensity and were s-polarized, with a power density of 0.4 W cm
±2, and the beam ratio was b = 1. The grating period was K = 3 lm in all cases. A reading bea...
