Division of Environmental Science and Engineering, Pohang University of Science and Technology (POSTECH) , Pohang 37673, Korea.
School of Chemical and Biological Engineering, Seoul National University , Seoul 151-742, Korea.
Environ Sci Technol. 2017 Jun 6;51(11):6590-6598. doi: 10.1021/acs.est.7b00774. Epub 2017 May 9.
Vertically aligned TiO nanotube arrays (TNTs) were prepared by electrochemical anodization, and then cathodically polarized with dark blue coloration for the dual-functional photoelectrochemical water treatment of organic substrates degradation and accompanying H generation. The resulting Blue-TNTs (inner diameter: ∼40 nm; length: ∼9 μm) showed negligible shift in X-ray diffraction pattern compared with the intact TNTs, but the X-ray photoelectron spectra indicated a partial reduction of Ti to Ti on the surface. The electrochemical analyses of Blue-TNTs revealed a marked enhancement in donor density and electrical conductivity by orders of magnitude. Degradations of test organic substrates on Blue-TNTs were compared with the intact TNTs in electrochemical (EC), photocatalytic (PC), and photoelectrochemical (PEC) conditions (potential bias: 1.64 V; λ > 320 nm). The degradation of 4-chlorophenol was greatly enhanced on Blue-TNTs particularly in PEC condition, whereas the PC activities of the Blue- and intact TNTs were similar. The potential bias of 1.64 V did not induce any noticeable activity in EC condition. Similar trends were observed for the degradation of humic acid and fulvic acid, where main working oxidants were found to be the surface hydroxyl radical as confirmed by hydroxyl radical probe and scavenger tests. H generation coupled with the organic degradation was observed only in PEC condition, where the H generation rate with Blue-TNTs was more than doubled from that of intact TNTs. Such superior PEC activity was not observed when a common TiO nanoparticle film was used as a photoanode. The enhanced electric conductivity of Blue-TNTs coupled with a proper band bending in PEC configuration seemed to induce a highly synergic enhancement.
垂直排列的 TiO 纳米管阵列(TNTs)通过电化学阳极氧化制备,然后通过阴极极化获得深蓝色,用于有机底物降解的双功能光电化学水处理和伴随的 H 生成。所得的蓝色-TNTs(内径:∼40nm;长度:∼9μm)与完整的 TNTs 相比,X 射线衍射图谱几乎没有变化,但 X 射线光电子能谱表明表面 Ti 部分还原为 Ti。蓝色-TNTs 的电化学分析表明施主密度和电导率显著提高了几个数量级。在电化学(EC)、光催化(PC)和光电化学(PEC)条件下(偏置电位:1.64V;λ>320nm)比较了蓝色-TNTs 和完整 TNTs 上测试有机底物的降解。在 PEC 条件下,4-氯苯酚的降解在蓝色-TNTs 上得到了极大的增强,而蓝色-TNTs 和完整 TNTs 的 PC 活性相似。1.64V 的偏置电位在 EC 条件下不会引起任何明显的活性。在腐殖酸和富里酸的降解中也观察到类似的趋势,其中确认主要工作氧化剂是表面羟基自由基,通过羟基自由基探针和清除剂测试证实了这一点。只有在 PEC 条件下观察到与有机降解偶联的 H 生成,其中蓝色-TNTs 的 H 生成速率比完整 TNTs 提高了一倍以上。当使用普通 TiO 纳米颗粒膜作为光阳极时,没有观察到这种优越的 PEC 活性。蓝色-TNTs 的增强导电性与 PEC 配置中的适当能带弯曲相结合,似乎诱导了高度协同增强。
