Electrically Controllable Liquid Crystal Component for Efficient Light Steering

Abstract

In this paper, we present an electrically controllable microoptical component for light beam steering and light intensity distribution built on the combination of nematic liquid crystal (LC) and polymer microprisms. Polymer microprism arrays are fabricated using soft embossing with elastic polydimethylsiloxane molds and ultraviolet curable resins. Surface profiling measurements show that the dimensions of the replicated prisms closely approximate those of the master prism. Two different LC alignment techniques were employed: hybrid rubbing alignment and obliquely evaporated $\hbox{SiO}_{2} $ alignment, both of which result in proper alignment of the LC molecules along the prism groove direction. The operation voltage of the LC components is relatively low (10 $\hbox{V}_{\bf rms} $ ) . The steering angle of a green laser beam was experimentally studied as a function of applied voltage, and a steering range of 3 $^{\circ} $ was found. The active LC components also effectively deflect a collimated white light beam over a steering angle of about 2 $^{\circ} $ with an efficiency of 27%–33%. All the optical measurements are in agreement with theoretical calculations based on Snell's law.