Nematic liquid crystals (NLC) are optically unaxial, birefringent materials. Molecular orientation of NLC could be altered from their equilibrium states by acoustic field. Variation of the polarized light intensity transmitted through a liquid crystal cell disturbed by acoustic waves is called the acousto-optical effect of NLC. This thesis presents an investigation on this effect induced by acoustic guided wave propagating in the liquid crystal layer sandwiched between two glass plates. The interdigital transducers fabricated on lithium niobate substrates were used to generate surface acoustic waves, which refracted into the liquid crystal layer through a coupling fluid. The transmitted laser intensity was measured as a quantitative index to interpret the acousto-optical effect because the nanometer-scale liquid crystal molecules are invisible. Besides that, a polarized microscope was also used to observe the phenomena accompanied with realignment of liquid crystal molecules due to acoustic guided waves. Experimental results indicate that liquid crystal molecules could be reoriented by acoustic guided waves. The transmitted laser intensity response extends to longer rise time with the increase of driving voltage for ultrasound. On the other hand, the fall time grows as the thickness of liquid crystal layer increases. The phase velocities of acoustic waves traveling in the liquid crystal cell slightly reduce with the increase of driving frequency. It reveals that the acoustic waves are dispersive. Iodine dye was used to observe the acoustic streaming induced by radiation of acoustic guided waves which were refracted through the coupling liquid layer in the present experimental setup. For the liquid crystal specimens having thickness greater than 25 μm, acoustic streaming field could be induced by radiation of acoustic guided waves. The acoustic streaming has an orientation perpendicular to the wavefront. Both acoustic radiation and acoustic streaming can change molecular orientation and induce local fluctuations of transmitted light intensity. It is found that the increase in thickness of liquid crystal layer also induces more extreme spikes in transmitted light intensity.