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掺杂金属阳离子的钽酸钠光催化剂:为何它们对水分解具有活性?

Sodium Tantalate Photocatalysts Doped with Metal Cations: Why Are They Active for Water Splitting?

作者信息

Onishi Hiroshi

机构信息

Department of Chemistry, School of Science, Kobe University, Rokko-dai, Nada, Kobe, Hyogo, 657-8501, Japan.

出版信息

ChemSusChem. 2019 May 8;12(9):1825-1834. doi: 10.1002/cssc.201802935. Epub 2019 Mar 26.

DOI:10.1002/cssc.201802935
PMID:30770649
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6593711/
Abstract

Sodium tantalate (NaTaO ) is the first semiconductor photocatalyst that produces hydrogen-oxygen mixed bubbles in the overall water splitting reaction, when appropriately doped with metal cations. A series of studies are reviewed herein to answer the question of why doping with metal cations raised the quantum efficiency of the reaction. Infrared absorption of band-gap-excited photocatalysts demonstrated that cation doping reduced the electron-hole recombination rate and the steady-state population of charge carriers accordingly increased. In-depth studies are focused on Sr cations incorporated through solid-state, flux, and hydrothermal reactions. The recombination rate was reduced when Ta cations were exchanged with Sr cations. Sodium cations were simultaneously exchanged to balance the cationic and anionic charges with no need for creating oxygen anion vacancies. NaTaO Sr(Sr Ta )O solid solution was formed as a result of the simultaneous doping. In addition to doping at the appropriate sites, the intraparticle distribution of Sr cations played an essential role to reduce the recombination rate. Strontium cations segregated to produce graded composition from the Sr-rich surface to the Sr-poor core. The bottom of the conduction band was raised at the Sr-rich surface and the excited electrons were driven to the Sr-poor core, leaving holes at the surface. However, the graded composition had a dual purpose; the excited electron population increased and its fractional contribution to the surface reaction decreased.

摘要

钽酸钠(NaTaO₃)是第一种在适当掺杂金属阳离子时,能在全分解水反应中产生氢氧混合气泡的半导体光催化剂。本文综述了一系列研究,以回答为何掺杂金属阳离子能提高反应的量子效率这一问题。带隙激发光催化剂的红外吸收表明,阳离子掺杂降低了电子 - 空穴复合率,相应地电荷载流子的稳态数量增加。深入研究聚焦于通过固态、助熔剂和水热反应掺入的Sr阳离子。当Ta阳离子被Sr阳离子交换时,复合率降低。同时交换钠离子以平衡阳离子和阴离子电荷,无需产生氧阴离子空位。由于同时掺杂,形成了NaTaO₃ - Sr(SrₓTa₁₋ₓO₃)固溶体。除了在适当位置进行掺杂外,Sr阳离子在颗粒内的分布对降低复合率也起着至关重要的作用。锶阳离子发生偏析,从富Sr表面到贫Sr核心产生梯度组成。在富Sr表面,导带底部升高,激发电子被驱动到贫Sr核心,在表面留下空穴。然而,这种梯度组成有双重作用;激发电子数量增加,但其对表面反应的分数贡献降低。

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