Lin Chiu-Hsun, Chao Jiunn-Hsing, Liu Chun-Hsuan, Chang Jui-Chun, Wang Feng-Chieh
Department of Chemistry, National Changhua University of Education, Changhua 500, Taiwan.
Langmuir. 2008 Sep 2;24(17):9907-15. doi: 10.1021/la800572g. Epub 2008 Aug 9.
Hydrogen trititanate (H 2Ti 3O 7) nanofibers were prepared by a hydrothermal method in 10 M NaOH at 403 K, followed by acidic rinsing and drying at 383 K. Calcining H 2Ti 3O 7 nanofibers at 573 K led to the formation of TiO 2 (B) nanofibers. Calcination at 673 K improved the crystallinity of the TiO 2 (B) nanofibers and did not cause any change in the morphology and dimensions of the nanofibers. TiO 2 (B) and H 2Ti 3O 7 nanofibers are 10-20 nm in diameter and several micrometers long, but FE-SEM reveals that several of these nanofibers tend to bind tightly to each other, forming a fiber bundle. Calcination at 773 K transformed TiO 2 (B) nanofibers into a TiO 2 (B)/anatase bicrystalline mixture with their fibrous morphology remaining intact. Upon increasing the calcination temperature to 873 K, most of the TiO 2 (B) nanofibers were converted into anatase nanofibers and small anatase particles with smoother surfaces. In the photocatalytic dehydrogenation of neat ethanol, 1% Pt/TiO 2 (B) nanofiber calcined at 673 K was the most active catalyst and generated about the same amount of H 2 as did 1% Pt/P-25. TPR indicated that the calcination of 1% Pt/TiO 2 (B) nanofiber at 573 K produced a poor Pt dispersion and poor activity. Calcination at a temperature higher than 773 K (in ambient air) resulted in an SMSI effect similar to that observed over TiO 2 in the reductive atmosphere. As suggested by XPS, such an SMSI effect decreased the surface concentration of Pt metal and created Pt (delta) sites, preventing Pt particles from functioning as a Schottky barrier and leading to a lower activity. Because of the synergetic effect between TiO 2 (B) and anatase phases, the bicrystalline mixture, produced by calcining at 773 K, was able to counter negative effects such as the reduction in surface area and the SMSI effect and maintained its photocatalytic activity.
通过水热法在403K的10M氢氧化钠中制备了氢钛酸(H₂Ti₃O₇)纳米纤维,随后进行酸性冲洗并在383K下干燥。在573K下煅烧H₂Ti₃O₇纳米纤维导致形成TiO₂(B)纳米纤维。在673K下煅烧提高了TiO₂(B)纳米纤维的结晶度,并且没有引起纳米纤维的形态和尺寸的任何变化。TiO₂(B)和H₂Ti₃O₇纳米纤维的直径为10 - 20nm,长度为几微米,但场发射扫描电子显微镜(FE - SEM)显示这些纳米纤维中的几根倾向于彼此紧密结合,形成纤维束。在773K下煅烧将TiO₂(B)纳米纤维转变为TiO₂(B)/锐钛矿双晶混合物,其纤维形态保持完整。当煅烧温度升高到873K时,大多数TiO₂(B)纳米纤维转变为具有更光滑表面的锐钛矿纳米纤维和小的锐钛矿颗粒。在纯乙醇的光催化脱氢反应中,在673K下煅烧的1% Pt/TiO₂(B)纳米纤维是最具活性的催化剂,产生的H₂量与1% Pt/P - 25产生的大致相同。程序升温还原(TPR)表明,在573K下煅烧1% Pt/TiO₂(B)纳米纤维产生的Pt分散性差且活性低。在高于773K的温度下(在空气中)煅烧导致类似于在还原气氛中在TiO₂上观察到的强金属 - 载体相互作用(SMSI)效应。如X射线光电子能谱(XPS)所表明的,这种SMSI效应降低了Pt金属的表面浓度并产生了Pt(δ)位点,阻止Pt颗粒作为肖特基势垒起作用并导致活性降低。由于TiO₂(B)和锐钛矿相之间的协同效应,通过在773K下煅烧产生的双晶混合物能够对抗诸如表面积减小和SMSI效应等负面影响并保持其光催化活性。
