宽光谱捕光材料的合成是实现高效太阳能人工光合制氢的基础，始终处于该研究领域的前沿。申请人长期从事可见光完全分解水制氢研究，通过氮原子掺杂开发了多个吸收带边至550 nm以上的新材料，并取得了目前"Z"机制粉末完全分解水制氢世界最高量子效率(6.8%@420 nm)。基于前期研究基础，本项目拟一方面以钙钛矿结构类d0金属基已知氧化物为研究对象，系统探讨杂原子引入的空间分布精准控制，实现兼具宽光谱响应和高载流子迁移率的新材料开发，另一方面通过理论模拟与高通量组合化学相结合制备无机-有机杂化类光催化新结构材料；以期合成一批吸收带边至600 nm以上、具有完全分解水制氢前景的目标材料，并通过表界面修饰和纳米粒子组装等方法协同构筑出3个以上宽光谱完全分解水制氢实际体系，发展杂原子引入调变能带结构和载流子迁移率等属性的一般性方法，促进材料结构与性能的“构效关系”认识，推动太阳能人工光合制氢科学发展。

Synthesis of novel materials with wide solar light absorption is basis of achieving efficient hydrogen production by artificial photosynthesis, and the topic has been a cutting edge frontier in the field of solar-to-chemical conversion. The applicant has been devoted to overall water splitting using photocatalysts with wide visible light utilization, and has developed some novel materials with absorption edge of beyond 550 nm. Using the as-developed materials as the H2-evolving side, the applicant has successfully fabricated Z-scheme overall water splitting system with apparent quantum efficiency of 6.8% @ 420nm, the current record value. Based on our previous research progress, this project is to develop some novel photocatalysts with absorption edge of beyond 600 nm and high carrier mobility for promising overall water splitting. On one hand, some known d0 metal-containing perovskite oxides will be doped by heteroatoms with an emphasis on precise control to their space distribution. On the other hand, synthesis of new inorganic-organic hybrid materials will be investigated by combining therotical simulation with high throughput experiments. Moreover, the surface and interface structures of some developed promising materials will be modified by nanostructure assemblying to construct over three real overall water splitting systems under visible light irradiation. Finally, it is expected to obtain a general methodology of adjusting energy band structure and carrier mobility by heteroatom doping, to deeply insight correlation between structures and performance of photocatalysts, and to advance science of artificial photosynthesis for hydrogen production from water.