| Autor: |
Zhang, Yangyu, Peng, Xuanbei, Tian, Han-Rui, Yang, Bo, Chen, Zuo-Chang, Li, Jiejie, Zhang, Tianhua, Zhang, Mingyuan, Liang, Xiaocong, Yu, Zhiyang, Zhou, Yanliang, Zheng, Lirong, Wang, Xiuyun, Zheng, Jian-Wei, Tang, Yu, Au, Chak-tong, Jiang, Lilong, Xie, Su-Yuan |
| Zdroj: |
Nature Chemistry; 20240101, Issue: Preprints p1-7, 7p |
| Abstrakt: |
Developing highly effective catalysts for ammonia (NH3) synthesis is a challenging task. Even the current, prevalent iron-derived catalysts used for industrial NH3synthesis require harsh reaction conditions and involve massive energy consumption. Here we show that anchoring buckminsterfullerene (C60) onto non-iron transition metals yields cluster-matrix co-catalysts that are highly efficient for NH3synthesis. Such co-catalysts feature separate catalytic active sites for hydrogen and nitrogen. The ‘electron buffer’ behaviour of C60balances the electron density at catalytic transition metal sites and enables the synergistic activation of nitrogen on transition metals in addition to the activation and migration of hydrogen on C60sites. As demonstrated in long-term, continuous runs, the C60-promoting transition metal co-catalysts exhibit higher NH3synthesis rates than catalysts without C60. With the involvement of C60, the rate-determining step in the cluster-matrix co-catalysis is found to be the hydrogenation of *NH2. C60incorporation exemplifies a practical approach for solving hydrogen poisoning on a wide variety of oxide-supported Ru catalysts. |
| Databáze: |
Supplemental Index |
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