Photochemical Acceleration of Ammonia Production by Pt 1 -Pt n -TiN Reduction and N 2 Activation.
Chengliang MaoJiaxian WangYunjie ZouYanbiao ShiCamilo J ViasusJoel Y Y LohMeikun XiaShufang JiMeiqi LiHuan ShangMireille GhoussoubYang-Fan XuJessica YeZhilin LiNazir P KheraniLirong ZhengYanjiang LiuLizhi ZhangGeoffrey A OzinPublished in: Journal of the American Chemical Society (2023)
Stable metal nitrides (MN) are promising materials to fit the future "green" ammonia-hydrogen nexus. Either through catalysis or chemical looping, the reductive hydrogenation of MN to MN 1- x is a necessary step to generate ammonia. However, encumbered by the formation of kinetically stable M-NH 1─3 surface species, this reduction step remains challenging under mild conditions. Herein, we discovered that deleterious Ti-NH 1─3 accumulation on TiN can be circumvented photochemically with supported single atoms and clusters of platinum (Pt 1 -Pt n ) under N 2 -H 2 conditions. The photochemistry of TiN selectively promoted Ti-NH formation, while Pt 1 -Pt n effectively transformed any formed Ti-NH into free ammonia. The generated ammonia was found to originate mainly from TiN reduction with a minor contribution from N 2 activation. The knowledge accrued from this fundamental study could serve as a springboard for the development of MN materials for more efficient ammonia production to potentially disrupt the century-old fossil-powered Haber-Bosch process.