A hybrid oxidation-microfiltration process is commonly used to remove ferric and manganese ions from groundwater through the rejection of ferric and manganese oxide on membrane. In oxidation, the manganese ions are more difficult to be oxidized than iron because they are inactive in water. Then the inoxidized manganese ions are frequently adsorbed in the pore of membrane and then continuously form oxidized particles, which result in a heavy irreversible fouling for membrane filtration. To reduce the irreversible fouling during membrane filtration, the formation of oxidized manganese before membrane filtration is the key to improve the performance of membrane filtration. Therefore, the study aims to investigate the effects of the formation of ferric and manganese oxidized particles on the behavior of membrane filtration in a preoxidation-microfiltration process. Before membrane filtration, the formation of oxidized particles in the solution of different Fe/Mn ratio at various mixing intensity was continuously monitored by a particle sizer to evaluate the effects of mixing on the characteristics of oxidized particles. After that, various solution containing oxidized particles was filtrated by microfiltration to determine the effects of particles properties on flux decline and cake resistance of membrane filtration. The result showed that the size of oxidized particles in solution containing the same Fe/Mn ratio decrease but the fractal dimension increase when mixing intensity was increased. By contrast, the size and fractal dimension of oxidized particles increased with increasing Fe/Mn ratio of solution under a constant mixing intensity. However, the particle formation is mainly affected by mixing intensity rather than the Fe/Mn ratio of solution. On the other hand, the cake resistance dominates the flux of membrane filtration. The structure of large oxidized particles is looser and easily compressed, which results in higher specific cake resistance. On the opposite, the small oxidized particles are more compact, which lead to the lower specific cake resistance. Furthermore, the Fe/Mn ratio of solution can influence significantly the cake resistance during membrane filtration. When the oxidized particles with more hydrophobic surfaces in solution of higher Fe/Mn ratio were filtrated by membrane, the average flux was lower. At such condition, the more severe irreversible fouling in membrane filtration also occurred.