催化作用
材料科学
共轭体系
石墨氮化碳
碳纤维
基质(水族馆)
氮化碳
过渡金属
吞吐量
氮气
纳米技术
氮化物
化学
光催化
有机化学
聚合物
复合数
图层(电子)
电信
海洋学
地质学
计算机科学
复合材料
无线
作者
Qiang Zhang,Xian Wang,Fuchun Zhang,Chunyao Fang,Di Liu,Qingjun Zhou
标识
DOI:10.1021/acsami.2c22519
摘要
TM-N x is becoming a comforting catalytic center for sustainable and green ammonia synthesis under ambient conditions, resulting in increasing interest in single-atom catalysts (SACs) for the electrochemical nitrogen reduction reaction (NRR). However, given the poor activity and unsatisfactory selectivity of existing catalysts, it remains a long-standing challenge to design efficient catalysts for nitrogen fixation. Currently, the two-dimensional (2D) graphitic carbon-nitride substrate provides abundant and evenly distributed holes for stably supporting transition-metal atoms, which presents a fascinating prospect for overcoming this challenge and promoting single-atom NRR. An emerging holey graphitic carbon-nitride skeleton with a C 10 N 3 stoichiometric ratio (g-C 10 N 3 ) from a supercell of graphene is constructed, which provides outstanding electric conductivity for achieving high-efficiency NRR due to the Dirac band dispersion. Herein, a high-throughput first-principles calculation is carried out to evaluate the feasibility of π–d conjugated SACs resulting from a single TM atom anchored on g-C 10 N 3 (TM = Sc–Au) for NRR. We find that W metal embedded in g-C 10 N 3 (W@g-C 10 N 3 ) can compromise the ability to adsorb the key target reaction species (N 2 H and NH 2 ), hence acquiring an optimal NRR behavior among 27 TM-candidates. Our calculations demonstrate that W@g-C 10 N 3 shows a well-suppressed HER ability and, impressively, a low energy cost of −0.46 V. Additionally, all-around descriptors are proposed to uncover the fundamental mechanism of NRR activity, among which a 3D volcano plot (limiting potential, screening strategy, and electron origin) uncovers the NRR activity trend, achieving a quick and high-efficiency prescreening for numerous candidates. Overall, the strategy of the structure- and activity-based TM-N x -containing unit design will offer useful insight for further theoretical and experimental attempts.
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