In this thesis, based on the photochemical scheme of PQ dye, we focus on the analyses and improvements of characteristics of Phenanthrenequinone-doped PMMA photopolymer in volume holographic recording. First of all, we elaborate the design strategy and preparation technique to fabricate a centimeter-scaled sample with low photo-induced shrinkage and high optical quality. The characteristics of the material in volume holographic recording are measured, such as dynamic range(M/#), sensitivity, and photo-induced shrinkage. The material is suitable for volume holographic applications. Base on the photo-chemical scheme, there are two clues for improving the dynamic range and sensitivity of our material. One is that the photoproduct, one-to-one combination of PQ and MMA monomer, induces refractive index change of the material. By adding multi-functional groups into the material, the dynamic range and sensitivity are improved. It is also shown that the concentration of multi-functional groups is increased by using the advanced fabrication procedure. Based the light-induced excitations of PQ, we propose a four-leveled model to describe the holographic recording dynamics of the material. According to the model, we can extend the range of wavelengths of recording light and explore another way to enhance the performance of the material. Therefore, the two-wavelength holographic recording is developed and demonstrated. The information can be selectively recorded by controlling the uniform illumination of UV gating beam. The information is non-volatile read by using red beam. We build a model to describe the photo-induced transitions of the dye during two-wavelength exposure. Base on agreements of the simulation and experimental results, the characteristics of the material can be further improved.