理论探究水溶液条件对TMNxCy催化氮还原性能的增强机制

doi:10.6023/A21040136

摘要/Abstract

在电化学氮还原(NRR)合成氨过程中, 为了认识真实水环境对过渡金属掺杂氮碳材料催化NRR活性的影响, 并筛选出实际催化性能最佳的构型, 本研究通过密度泛函理论(DFT)和从头算分子动力学(AIMD)相结合的方法, 对一系列不同配位形式的过渡金属掺杂氮碳催化剂(TMN_xC_y, TM=Sc、Ti、V、Cr、Mn、Fe、Co、Ni、Cu、Zn; x=1~4; y=4–x, 总共40种构型)催化NRR的热力学稳定性和实际氮还原催化活性进行了系统研究. 计算结果表明, 本工作所研究的40种催化剂结构均具有较高的热力学稳定性, 可作为实际的NRR候选催化剂. 其中, 利用隐性+显性水溶剂模拟真实水环境时, 过渡金属V掺杂形成的VN₃C₁结构催化NRR酶机制过程的最大吉布斯自由能变值仅为0.35 eV (在U=0 V vs. RHE时), 表现出最佳的NRR催化性能. 总体而言, 本研究采用DFT与AIMD相结合的方法, 深入地阐述了TMN_xC_y催化剂的实际NRR催化过程, 为实验过程做出了更为贴切的理论预测.

关键词: 电化学氮还原, 过渡金属掺杂氮碳材料, 密度泛函理论, 从头算动力学

Currently, the electrocatalytic nitrogen reduction reaction (NRR) is a significant catalytic process under ambient conditions. For the N₂ fixation reaction, the metal-based catalysts are the most widely explored catalysts, but compared to the traditional Haber-Bosch process, the poor resistance and low selectivity to acids or bases, and the low Faradaic efficiency, production rate, and stability of metal-based catalysts, make them uncompetitive with industrial N₂ fixation. During these years, inspired by applications of carbon material catalysts for electrocatalytic field, the carbon material catalysts have attracted great attention, especially for transition-metal-doped carbon material catalysts. In this work, to obtain insight into the influence of water ambient condition on the catalytic performance of transition-metal-doped carbon material catalyst for electrochemical NRR, and to screen out the optimal catalyst structure with excellent catalytic performance, herein, under actual ambient conditions, we systematically described the thermodynamic stability and catalytic performance of a series of transition-metal-doped carbon material catalysts (TMN_xC_y, TM=Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, x=1~4, y=4–x, 40 models) for NRR by means of density functional theory (DFT) and ab initio molecular dynamics (AIMD) simulations. To simulate water condition during the NRR, we employed a mixed implicit+explicit solvation model, in which explicit water molecules are included in the first solvation shell, forming hydrogen bonds with the intermediate adsorbates of NRR, and an implicit solvent model captured longer-range solvation effects. The calculation results indicate that the 40 catalysts possess high thermodynamic stability, even at 700 K, and can be used as potential catalysts toward ammonia synthesis. It is noted that VN₃C₁ catalyst exhibits the best performance via a NRR enzymatic pathway under the actual water ambient condition with a mixed implicit+explicit solvation model, which has a lowest change value of free energy of 0.35 eV (at U=0 V vs. RHE) for potential-determining step. These results may reveal a new perspective for artiﬁcial ammonia synthesis using a single-atom catalyst under actual ambient conditions.

Key words: electrochemical nitrogen reduction reaction, transition-metal-doped carbon material, DFT, AIMD

引用此文

熊昆, 陈伽瑶, 杨娜, 蒋尚坤, 李莉, 魏子栋. 理论探究水溶液条件对TMN_xC_y催化氮还原性能的增强机制[J]. 化学学报, 2021, 79(9): 1138-1145.

Kun Xiong, Jiayao Chen, Na Yang, Shangkun Jiang, Li Li, Zidong Wei. Theoretical Research on Catalytic Performance of TMN_xC_y Catalyst for Nitrogen Reduction in Actual Water Solvent[J]. Acta Chimica Sinica, 2021, 79(9): 1138-1145.

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图/表 5

图1. (a) TMN4, TMN3C1, TMN2C2和TMN1C3结构示意图; (b)各体系的形成能(Eformation)及结合能与内聚能的差值(Ebinding–Ecohesive)

Figure 1. (a) The geometry of TMN4, TMN3C1, TMN2C2 and TMN1C3; (b) the formation energy and (Ebinding–Ecohesive) of TMNxCy structures

图2. 在300 K真空条件下, 10 ps的AIMD模拟过程中: (a, c) ScN1C3和ZnN3C1的骨架结构变化; (b, d) ScN1C3和ZnN3C1体系温度和能量变化

Figure 2. (a, c) The geometry structure; (b, d) variation of temperature and total energy of ScN1C3 and ZnN3C1 within 10 ps during AIMD simulation at 300 K

图3. ScN1C3和ZnN3C1结构在300 K水溶液环境下, 5 ps的AIMD模拟过程中: (a, d) 骨架结构变化; (b, e) 体系温度和能量变化; (c, f) 金属原子掺杂附近关键键长的变化

Figure 3. (a, d) The geometry structure; (b, e) variation of temperature and total energy; (c, f) variation of bond length near doped metal atoms for the ZnN3C1 and ScN1C3 with 50 H2O in 5 ps during AIMD simulation at 300 K

图4. (a)三种可能的氮还原反应机理; TMNxCy催化剂表面上*NNH、*N*NH和*NH2的(b)吸附构型和(c)吸附能

Figure 4. (a) Schematics of three possible associative mechanisms for NRR; (b) the optimized geometries and (c) adsorption energies of *NNH, *N*NH and *NH2 on various TMNxCy surface

图5. U=0 V (vs. RHE)时, TMNxCy (TM=Ti, V, Cr, Mn, Fe和Co)在隐性溶剂化条件下催化NRR通过(a)末端机理和(b)酶机理的吉布斯自由能; NRR相关物种在显性溶剂中的吸附构型(c) FeN3C1和(d) VN3C1; 及相应的吉布斯自由能(e) FeN3C1(末端机理)和(f) VN3C1(酶机理)

Figure 5. At U=0 V (vs. RHE), the Gibbs free energy diagrams for NRR on TMNxCy (TM=Ti, V, Cr, Mn, Fe and Co) catalysts via (a) distal and (b) enzymatic mechanisms with implicit solvation model. The reaction intermediates structures of (c) FeN3C1 and (d) VN3C1 catalysts with explicit solvation model. Gibbs free energy diagrams on (e) FeN3C1 and (f) VN3C1 via distal and enzymatic mechanism, respectively

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