化学
光催化
催化作用
载流子
超晶格
光谱学
过渡金属
光化学
化学物理
光电子学
材料科学
有机化学
量子力学
物理
作者
Huiyi Li,Qinglong Wu,Lei Li,Liang Sun,Min Ge,Qilong Liu,Chong Xiao,Qun Zhang,Yi Xie
摘要
Transition metal-catalyzed C-N cross-coupling reactions are pivotal in synthesizing pharmaceuticals and agrochemicals. Nickel catalysts, while cost-effective, suffer from rapid deactivation via reductive elimination, leading to reaction instability. Photocatalysis using photogenerated charge carriers offers a promising solution to mitigate metal catalyst deactivation, yet their efficacy remains constrained by inefficient electron-hole separation, which reduces the overall catalytic performance. Herein, we propose a polarization-ordered tandem strategy to integrate multiple continuous charge carrier drivers into superlattice photocatalysts, enabling efficient charge carrier separation over a broader spatial range. Taking Bi4TaO8Cl-Bi2YO4Cl superlattice as an example, aberration-corrected electron microscopy and atomic-resolution elemental mapping confirm the successful construction of the superlattice structure. Combined with fluorescence spectroscopy, Kelvin probe spectroscopy, and ultrafast spectroscopy, our results indicate that the ordered polarization tandem between the constituent layers significantly lowers the exciton binding energy, improving carrier transfer efficiency and charge separation. Consequently, efficient electron-hole separation effectively suppresses nickel deactivation during C-N coupling reactions. Bi4TaO8Cl-Bi2YO4Cl can achieve a high conversion (99%) and selectivity (99%) to couple pyrrolidine and 4-bromobenzonitrile under visible light within 2 h. The presented strategy not only effectively mitigates the deactivation of transition metal catalysts in C-N coupling reactions but also opens new avenues for enhancing the efficiency of traditional photocatalytic processes.
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