电催化剂
电子转移
催化作用
密度泛函理论
化学
化学物理
选择性
氨
吸附
石墨烯
电荷(物理)
材料科学
催化循环
电子结构
计算化学
反应机理
机制(生物学)
氨生产
活动站点
亚硝酸盐
电子
态密度
电荷密度
电极
电子密度
动能
结合能
无机化学
电子定域函数
作者
Rui Zheng,ZhengCheng Wen,Ruixue Li,Xiaohui Tang,Heping Li,Yuan Li,Sicong Zhu
标识
DOI:10.6084/m9.figshare.30988292
摘要
The revised abstract (191 words) is below: The electrocatalytic reduction of nitrite (NO₂RR) to ammonia is of great significance for the nitrogen cycle and environmental remediation. Here, density functional theory is employed to investigate the catalytic performance of Co-based dual-atom catalysts anchored on 2D N-doped graphene (Co-M/CN₆, M = Mn, Fe, Ni, Cu, Zn) for NO₂RR, aiming to reveal the underlying reasons affecting the catalytic efficiency of eNO2RR. Results show that CoFe electrocatalyst exhibited excellent NO₂RR activity, with the energy barriers of the rate determining steps (ΔGRDS) as low as 0.58 eV. The introduction of Fe accelerates the charge transfer between reaction intermediates and active sites by regulating the electronic structure of the catalyst, significantly reducing the reaction energy barrier. The selectivity for NO₂RR is discussed by comparing the ΔGRDS of HER with the ΔGRDS of NO2RR. It is also found that the CoFe catalysts can effectively inhibit the competitive HER. By using multiple descriptors (pCOHP, d-band center, electron localization function (ELF), free energy of *NO₂ adsorption (ΔG*NO₂), Bader charge transfer, charge density difference) to analyze electronic and energetic factors, it is further revealed that the promoting effects of Fe are closely related to the electron transfer ability.
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