Ito Nathalie Minko, Carvalho Waldemir Moura, Muche Dereck Nills Ferreira, Castro Ricardo Hauch Ribeiro, Dalpian Gustavo Martini, Souza Flavio Leandro
Centro de Ciências Naturais e Humanas (CCNH), Universidade Federal do ABC, Av. dos Estados No. 5001, Bangu, Santo André, São Paulo CEP 09210-580, Brazil.
Phys Chem Chem Phys. 2017 Sep 20;19(36):25025-25032. doi: 10.1039/c7cp04827k.
Here we show that chlorine species originating from commonly used iron precursors annihilate the hematite nanorod photocurrent by providing recombination pathways. Although hematite nanorod films could be obtained by thermal decomposition of the iron oxyhydroxide phase (β-FeOOH), indistinguishable photocurrent responses under dark and sunlight irradiation conditions were observed until the nanorods were annealed (activated) at 750 °C. The annealing led to the elimination of observable chlorine species and allowed photocurrent responses of 1.3 mA cm at 1.23 V vs. RHE, which is comparable to the best results found in the literature, suggesting that residual chlorine species from the synthesis can act as electron traps and recombination sites for photogenerated holes.
我们在此表明,源自常用铁前驱体的氯物种通过提供复合途径消除了赤铁矿纳米棒的光电流。尽管可以通过氢氧化铁相(β-FeOOH)的热分解获得赤铁矿纳米棒薄膜,但在将纳米棒在750°C退火(活化)之前,在黑暗和阳光照射条件下观察到的光电流响应并无差异。退火导致可观察到的氯物种消除,并在相对于可逆氢电极(RHE)为1.23 V时产生了1.3 mA cm的光电流响应,这与文献中发现的最佳结果相当,表明合成过程中残留的氯物种可作为光生空穴的电子陷阱和复合位点。
