Nanoimprint lithography (NIL) is one of the most promising candidates for the next generation due to the advantages of high resolution, high throughput, low cost, and the ease of fabricating nanoscale patterns. In this thesis, we directly imprinted sub-micrometer patterns on plastic substrates. For the master mold without release layer, we used ice water as a heat conductor to solve the adhesion problem between the master mold and substrate. With directly imprinting on polymer substrates, we can transfer the pattern of master mold to the substrate directly and fabricate flexible optical diffraction devices, such as phase mask, and sub-wavelength optical wave plates with single- or dual-side grating patterns. Optical wave plates fabricated by nanoimprint lithography on flexible substrates have advantages of rapid process and low-cost. Besides, we can combine wave plates with different phase retardation together to obtain various phase retardation of wave plates. The period of the flexible phase mask is 2μm. With the optimal process parameters, we obtain 3% zero-order intensity of phase mask. Applications of phase mask on producing patterns on photo-resist on flexible PET substrates are also discussed. We observe two experimental results: First, a pattern of gradually changing period is obtained when the flat phase mask is putting on the bent PET substrate. Second, we obtain a pattern featuring the same line-width and period with the master mold by alternate exposure process when the phase mask and PET substrate are simultaneously bent.