Transmission variations in liquid crystal spatial light modulators caused by interference and diffraction effects

Abstract

We report on the characteristics of a newly developed high-resolution (640×480 pixels) parallel-aligned liquid crystal spatial light modulator (LCSLM) as a function of wavelength. Phase-only operation over a range of 2π rad is easily achieved by operating at shorter wavelengths. We also measure an unexpected effect—the transmitted light intensity changes with applied voltage. Our experiments show that thin-film interference and pixel diffraction effects are responsible for this observed behavior. The diffraction effect is caused by a nonuniform electric field across each pixel. This nonuniform electric field introduces a blazing effect that changes the intensity distribution in the various diffracted orders as a function of applied voltage. These same kinds of effects have been observed with several other twisted-nematic LCSLMs. Because of the complicated polarization effects caused by these twisted-nematic liquid crystal devices, however, the diffraction and interference effects are more easily studied using the parallel-aligned LCSLM. © 1999 Society of Photo-Optical Instrumentation Engineers.