This dissertation shows how the morphology and polymorphism of poly(vinylidene fluoride) (PVDF) membranes prepared by using vapor-induced phase separation (VIPS) and liquid-induced phase separation (LIPS) were tuned by varying the dissolution temperature at which PVDF was dissolved (Tdis) to form the casting solution, without changing any other membrane preparation conditions. We also investigated the formation mechanism in the morphology and polymorphism and set up an index of controlling the membrane structure. The results showed that there existed an important transition dissolution temperature (Tdis), being referred to as the “critical dissolution temperature, Tcri”, across which the morphology and polymorphism of membranes drastically changed. With a Tdis higher than the Tcri, the prepared membranes were composed of nodules and the size of polymer domain (nodules) decreased as the Tdis decreased. Because the polymer rich phase could freely coarsen to a large domain during the phase separation, we called the system “free coarsening”. With a Tdis lower than the Tcri, the coarsening was suppressed so the membranes with lacy (bi-continuous) structure were obtained. Because the polymer chains hardly coarsened during the phase separation, we called the system “hindered coarsening”. Therefore, the morphologies were classified into hindered and free coarsening by Tcri. The Tcri was an indicator that the domain grew or not. The phenomenon was considered as general, as a Tcri was observed for all the three solvents, N-methyl-2-pyrrolidone (NMP), dimethylacetamide (DMAc) and N,M-dimethylformamide (DMF), and the non-solvents, water and a series of alcohols, used in the present study. All the results indicated that the phenomena were general and not limited to a specific solvent and nonsolvent. We proposed that the Tdis affect the membrane morphology by changing the density of the nuclei for the crystallization contained in the casting solution. Lower Tdis resulted in higher nuclei density. The difference of nuclei density in the casting solution caused the different behaviours of gelation and crystallization which were testified in the falling-ball experiment, the observation of IR spectra. And two gelling processes were proposed, Non-crystallization-initiation gelling (NC-gelling) and Crystallization-initiation gelling (C-gelling). The NC-gelling and C-gelling could be determined by Tcri. During VIPS process, the crystallization happened prior to L-L demixing. With TdisTcri, solution started to gel with formation of ordered conformations, so the crystal domain grew more freely. The domain formed nodules structure with dense surface by the driving force of the crystallization. When membranes prepared by LIPS with employing iso-propanol (iPA) as nonsolvent, the solvent exchanged with nonsolvent quickly, which caused the composition route enter the spinodal decomposition. Therefore, the membrane with bi-continuous structure was obtained. With Tdis>Tcri, because the crystallization happened sequentially, the polymer rich phase coarsened to nodules from bi-continuous structure for a solution with low gelation degree. Because of the competition between the coarsening and solidification, the polymer rich phase formed nodules with porous surface. On the contrary, for a solution with high nuclei density, the solution still could gel quickly. There the coarsening was suppressed. The solution formed translucent gel and revealed the bi-continuous structure after the L-L demixing. When IPA was replaced by normal-octanol (nOct), the L-L demixing curve moved toward to nonsolvent. Accordingly, the composition route on theoretical phase diagram could stay in the crystallization region for a longer time. Therefore, the similar result as membrane prepared by VIPS was obtained. In addition, the polymorphism of a PVDF membrane was not only affected by Tdis but also controlled by competition between the crystallization and the L-L demixing. For the polymorph evolution with the Tdis, when the crystallization was prior to the L-L demixing, alpha form can be favorably formed in solution with high nuclei density. The beta form prevailed as the Tdis increased to be higher than the Tcri. If the L-L demixing was prior to the crystallization, alpha form was mainly observed in membrane no matter which Tdis we used. Therefore, the crystallization was classified into hindered crystallization and free crystallization. The hindered crystallization is indicative of polymer chains ordered in a harsh environment, like NC-gelling process or the L-L demixing, and then polymer chains preferred to form the alpha form. If the polymer chains moved easily, the free crystallization can happen. The free crystallization resulted in beta form due to the solvent polarity. Finally, our works give a clear view about the competition between the crystallization and the L-L demixing, and point out the effect of nuclei density in membrane preparation. We propose that the competition between the two gelling processes play an important role in determining the PVDF membrane morphology and crystalline polymorphs, and the dissolution temperature can change the competition. The critical dissolution temperature can be interpreted as a dissolution temperature across which the dominant gelling process switched. The explanation shows a window how to prepare a bi-continuous membrane with alpha form, porous nodules with alpha form and dense nodules with beta form.