Shanghai Research Institute of Petrochemical Technology, Sinopec , Shanghai 201208 , China.
ACS Appl Mater Interfaces. 2018 Aug 1;10(30):25321-25328. doi: 10.1021/acsami.8b05925. Epub 2018 Jul 18.
A facial hydrothermal method is applied to synthesize bismuth subcarbonate (BiOCO, BOC) with controllable defect density (named BOC- X) using sodium bismuthate (NaBiO) and graphitic carbon nitride (GCN) as precursors. The defects of BOC- X may originate from the extremely slow decomposition of GCN during the hydrothermal process. The BOC- X with optimal defect density shows a photocatalytic nitrogen fixation amount of 957 μmol L under simulated sunlight irradiation within 4 h, which is 9.4 times as high as that of pristine BOC. This superior photocatalytic performance of BOC- X is attributed to the surface defect sites. These defects in BOC- X contribute to a defect level in the forbidden band, which extends the light-harvest region of the photocatalyst from the ultraviolet to the visible-light region. Besides, surface defects prevent electron-hole recombination by accommodating photogenerated electrons in the defect level to promote the separation efficiency of charge carrier pairs. This work not only demonstrates a novel and scalable strategy to synthesize defective BiOCO but also presents a new perspective for the synthesis of photocatalysts with controllable defect density.
采用面部水热法,以偏铋酸钠(NaBiO)和石墨相氮化碳(GCN)为前驱体,合成了具有可控缺陷密度的碳酸氧铋(BiOCO,BOC)(命名为 BOC-X)。BOC-X 的缺陷可能来源于水热过程中 GCN 的极慢分解。在模拟太阳光照射下,具有最佳缺陷密度的 BOC-X 在 4 小时内的光催化固氮量达到 957 μmol·L-1,是原始 BOC 的 9.4 倍。BOC-X 的这种优越的光催化性能归因于表面缺陷位。BOC-X 中的这些缺陷导致禁带中的缺陷能级,从而将光催化剂的光捕获区域从紫外光扩展到可见光区域。此外,表面缺陷通过在缺陷能级容纳光生电子来防止电子-空穴复合,从而促进载流子对的分离效率。这项工作不仅展示了一种合成缺陷 BiOCO 的新颖且可扩展的策略,而且为具有可控缺陷密度的光催化剂的合成提供了新的视角。
