Decomposition of Banten ilmenite by caustic fusion process for TiO2 photocatalytic applications has been done. Caustic fusion process using NaOH to obtain sodium titanate compound which is soluble in sulfuric acid (H2SO4) to produces TiOSO4 as a precursor. Synthesis of TiO2 from TiOSO4 precursors by variations of pH hydrolysis are 1.0 (TiO2 A), 1.5 (TiO2 B) and 2.0 (TiO2 C). XRD pattern identified TiO2 structures crystals are anatase phase and traces α-Fe2O3 as an impurity. Presence of Fe2O3 as an impurities give positive effect on TiO2 photocatalytic activity that is to narrower the band gap energy thus facilitates of electrons excitation from valence band to conduction band and enlarge the specific surface area thus reaction between Rhodamin B solution and TiO2 surface can be faster. TiO2 A, TiO2 B and TiO2 C was compared to TiO2 M (commercial TiO2) in Rhodamin B solution for the photocatalytic activity where the maximum TiO2 degradation efficiency was obtained at TiO2 C 80.0 % while TiO2 M 59.8 %.
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机译:已经完成了通过苛性硅酸盐的分解,用于TiO2光催化应用的苛性硅酸盐。使用NaOH获得溶于硫酸(H 2 SO 4)的钛酸钠化合物以产生TiSO4作为前体的苛性钠化合物。通过pH水解的变化合成TiOS4前体的TiO 2是1.0(TiO 2 A),1.5(TiO 2 B)和2.0(TiO 2 C)。 XRD图案鉴定TiO2结构晶体是锐钛矿相,并且痕量α-Fe 2 O 3作为杂质。作为杂质的Fe 2 O 3的存在对TiO 2光催化活性产生阳性作用,即较窄的带隙能量,从而使电子激发从价带促进到导带和扩大比表面积,因此rhodamin B溶液和TiO2表面之间的反应可以更快。将TiO 2 A,TiO 2 B和TiO 2 C进行比较至罗丹明蛋白B溶液中的TiO 2 M(商业TiO2),用于在TiO 2 C 80.0%在TiO 2 C 80.0%获得最大TiO 2降解效率的情况下。
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