Chemically Bonded Schottky Junction for Efficient N<sub>2</sub> Photofixation
Yin Bi, Yuan Fang, Ling Yuan, Jiaxin Li, Chaoqi Zhang, Pengyue Shan, Xinchan Zhang, Chao Liu, Chengzhong Yu
Abstract
Construction of the Schottky junction is a promising strategy for realizing efficient photocatalytic N 2 fixation; however, the reported Schottky junction photocatalysts are mainly constructed via physical stacking or Van der Waals interaction with much room to improve performance. Herein, a chemically bonded Schottky junction photocatalyst is constructed for the fixation of N 2 to NH 3 production. The photocatalyst exhibits a unique 1D necklace-like morphology with hollow ZnCo bimetal sulfide (ZnCoS x ) nanocages strung by carbon nanotubes (CNTs). Experimental and theoretical results reveal that the formation of C–O–Co chemical bonds at the interface not only provides an atomic transportation highway for charge transfer but also modulates the electronic structure of Co active sites toward enhanced N 2 chemisorption and activation. The elaborately designed CNT/ZnCoS x junction with a chemically bonded interface exhibits superior nitrogen fixation activity with an NH 3 yield of 1644 μmol g –1 h –1 in pure water. This study paves the way for the development of efficient Schottky junction photocatalysts for their applications.