Zou Hai, Qi Yu, Du Shiwen, Bao Yunfeng, Xin Xueshang, Fan Wenjun, Xiao Yejun, Jin Shengye, Feng Zhaochi, Zhang Fuxiang
State Key Laboratory of Catalysis, Dalian National Laboratory for Clean Energy, Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Zhongshan Road 457, Dalian 116023, P. R. China.
State Key Laboratory of Molecular Reaction Dynamics and Dynamics Research Center for Energy and Environmental Materials, Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian 116023, China.
J Am Chem Soc. 2024 Oct 16;146(41):28182-28189. doi: 10.1021/jacs.4c08001. Epub 2024 Oct 4.
Photocatalysis is an intricate process that involves a multitude of physical and chemical factors operating across diverse temporal and spatial scales. Identifying the dominant factors that influence photocatalyst performance is one of the central challenges in the field. Here, we synthesized a series of perovskite RTaON semiconductors with different A-site rare earth atoms (R = Pr, Nd, Sm, and Gd) as model photocatalysts to discuss the influence of the A-site modulation on their local structures as well as both physical and chemical properties and to get insight into the rate-determining step in photocatalytic Z-scheme overall water splitting (OWS). It is interesting to find that, with a decreasing ionic radius of the A-site cations, the RTaON compounds exhibit continuous blue shift of light absorption and a concomitant reduction in the lifetime of photogenerated carriers, revealing a significant influence of A-site atoms on the light absorption and charge separation processes. On the other hand, the A-site atomic substitution was revealed to significantly modulate the valence band positions as well as surface oxidation kinetics. By employing the Pt-modified RTaON as H-evolving photocatalysts, the activity of photocatalytic Z-scheme OWS for hydrogen production on them is found to be determined by its surface oxidation process instead of light absorption or charge separation. Our results give the first experimental demonstration of the rate-determining step during the photocatalytic Z-scheme OWS processes, as should be instructive for the design and development of other efficient solar-to-chemical energy conversion systems.
光催化是一个复杂的过程,涉及在不同时间和空间尺度上起作用的众多物理和化学因素。确定影响光催化剂性能的主要因素是该领域的核心挑战之一。在此,我们合成了一系列具有不同A位稀土原子(R = Pr、Nd、Sm和Gd)的钙钛矿RTaON半导体作为模型光催化剂,以讨论A位调制对其局部结构以及物理和化学性质的影响,并深入了解光催化Z型全水分解(OWS)中的速率决定步骤。有趣的是发现,随着A位阳离子离子半径的减小,RTaON化合物表现出光吸收的连续蓝移以及光生载流子寿命的相应缩短,揭示了A位原子对光吸收和电荷分离过程的重大影响。另一方面,A位原子取代被发现会显著调节价带位置以及表面氧化动力学。通过使用Pt修饰的RTaON作为析氢光催化剂,发现它们上用于制氢的光催化Z型OWS活性由其表面氧化过程而非光吸收或电荷分离决定。我们的结果首次通过实验证明了光催化Z型OWS过程中的速率决定步骤,这对其他高效太阳能到化学能转换系统的设计和开发应具有指导意义。
