Fringe-field-induced out-of-plane reorientation in vertically aligned nematic spatial light modulators and its effect on light diffraction

Abstract

ABSTRACT Liquid crystal (LC)-based spatial light modulators (SLMs) have the ability to shape the wavefront of a light beam and are widely used in applications where phase or amplitude modulation is required. In this work we study the LC director configuration in vertically aligned nematic (VAN) SLMs, with a focus on 1D binary gratings with different driving voltages. By comparing experimental microscopy measurements with simulations, we demonstrate that the director can rotate out of the plane determined by the pretilt of the SLM. By twisting out of the pretilt plane, the formation of a reverse tilt zone in the LC director configuration is avoided. The twist effect is asymmetric and only occurs at the edges where the fringe-field of the high voltage pixel is inclined in the same direction as the pretilt. Due to the out-of-plane reorientation of the director at one side of the pixel, binary gratings show strongly asymmetric diffraction in the pretilt plane. The out-of-plane reorientation also induces changes in the polarisation state of the light beam and the competition between two different out-of-plane reorientation directions may lead to slow switching. It is therefore of utmost importance to consider this effect when using VAN SLMs in applications.