A novel strategy was applied in the synthesis of gamma-Fe2O3 pillared bentonite (y-Fe2O3-P-Bent) by intercalating Fe3+ into bentonite in the presence of the surfactant CAB as an expanding agent and template agent. Then gamma-Fe2O3-P-Bent catalyst was used as a heterogeneous catalyst for photo-Fenton degradation of organic contaminants. CTAB can promote the formation of crystalline gamma-Fe2O3 in the process of calcination. In addition, the CTAB also significantly increased the surface area of the composites. Only the alpha-Fe2O3 pillared bentonite (alpha-Fe2O3-P-Bent) could be obtained under the same conditions without CAB. The as-obtained composites were well characterized by various techniques to study their morphological, structural and magnetic properties. The specific surface area of the gamma-Fe2O3-P-Bent catalyst increased from 29 to 117 m(2)/g compared to bentonite. The saturated magnetization (Ms) values of gamma-Fe2O3-P-Bent was 10 emu/g. The effects of various reaction parameters such as H2O2 dosage, initial pH value, gamma-Fe2O3-P-Bent dosage on the degradation of RhB were studied. Under the best conditions (0.2 g/L of catalyst, 10 mM of H2O2), the gamma-Fe2O3-P-Bent catalyst displayed to possess superior degradation ability to Rhodamine B (RhB) comparing the results with the alpha-Fe2O3-P-Bent. The catalyst showed efficient for the degradation of other organic dyes as well. After five reaction cycles the catalyst still showed high photocatalytic activity (91%), which showed that the magnetic catalyst possessed very stable, highly reactive, and easy to separate by an external magnetic field. Hence, this facile and high efficiency method may be extended to fabricate other types of magnetic materials.

• 出版日期2017-2
• 单位华东理工大学; 化学工程联合国家重点实验室; 石河子大学