Recently, the mechanical effects of light on objects greatly attract many scientists. To be more specific, though the effect of light on objects at macroscopic scale is unobvious, we can find obvious influence on the objects if we observe in the scale below micron. Therefore, Optomechanics has become a very popular topic in recent years. However, the light strikes the dielectric waveguide with the waveguide geometry is symmetrical, the moments generated by the left and right structures will cancel each other out and the overall net torque will approach zero. Thus, in order to reduce the positive and negative moment cancellation phenomenon, we must change the geometry and increase the net torque of the overall structure. In this Thesis, we use the finite element method to simulate the steady-state electromagnetic field of various dielectric waveguides and then substitute the electromagnetic field of the surface into the Maxwell stress equation to obtain the stress applied by the electromagnetic field on the waveguide surface and finally calculate the integrated of the surface stress and the point-to-center for the average torque of the waveguide is obtained. We try to change the shape of the waveguide to impel of the distribution of the field, and then observe the different of the force distribution to find the structure of the maximum moment. The results show that it can indeed enhance the torque by the voids in the waveguide, the asymmetry and the directly illuminated surface. Yet the structure rotates with the maximum value of the average moment, it may be different from the maximum value at a fixed angle, and the rotation of the light receiving surface may be greatly affected. In summary, the asymmetry shape and the light-receiving surface are as perpendicular as possible to the overall structure will obtain the best performance of the average moment.