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研究生: 辜敏韶
KU, Min-Shao
論文名稱: 以理論計算方法探討CO在Cu(711)表面上的電化學還原
Computational Electrochemical Reduction of CO on Cu(711) surface
指導教授: 蔡明剛
Tsai, Ming-Kang
學位類別: 碩士
Master
系所名稱: 化學系
Department of Chemistry
論文出版年: 2019
畢業學年度: 107
語文別: 中文
論文頁數: 51
中文關鍵詞: 理論計算Cu(711)CO2
英文關鍵詞: Theoretical calculation, Cu(711), CO2
DOI URL: http://doi.org/10.6345/NTNU201900830
論文種類: 學術論文
相關次數: 點閱:133下載:0
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  • 在現今社會中,使用銅做為電催化電極是現今將二氧化碳電還原成許多有用的燃料的其中一項主要方法。透過製備不同的銅電極材料表面來區分各種催化途徑成為CO2電還原化學最關注的主題之一;而催化體系設計的成功與否,取決於是否提高還原CO2的選擇性。利用理論計算,我們研究Cu(711)表面,以了解早期實驗觀察所顯示的C-C耦合的有趣選擇性。通過分析沿著CO2還原機理的各種關鍵中間體的電子結構,可以為設計用於Cn(n≥2)烴合成的Cu電極材料的新形態提供進一步的見解。

    Carbon dioxide can be electrochemically reduced to many useful fuels using copper electrocatalysts. The differentiation of the various catalytic pathways by the preparation of Cu electrode materials becomes one of the most concerned topics for the CO2 electroreduction chemistry. The enhancement in the CO2 reduction selectivity determines the success of catalytic system design. Through theoretical calculations, we investigate Cu(711) surface in order to understand the intriguing selectivity for the C-C coupling shown by the early experimental observation. By analyzing the electronic structure of the various critical intermediates along the CO2 reduction mechanism, it will be possible to provide further insights for designing the new morphology of Cu electrode materials for Cn (n ≥ 2) hydrocarbon synthesis.

    中文摘要 I 英文摘要 II 總目錄 III 圖目錄 V 表目錄 VI 第一章 緒論 1 第二章 理論計算與方法 4 §2-1 固態材料的電子結構理論 4 §2-1-1 密度泛函理論 4 §2-1-2 局部密度近似法 (Local Density Approximation, LDA) 6 §2-1-3 廣義梯度近似法 (Generalized Gradient Approximation, GGA) 7 §2-1-4 空間週期性 (periodic boundary condition) 7 §2-1-5 布洛赫定理(Bloch Theorem) 8 §2-1-6 虛位勢 (pseudopotential) 9 §2-2 分子力學 (MOLECULAR MECHANICS, MM) 13 §2-2-1 分子動力學(Molecular Dynamic, MD) 14 §2-3 計算方法 16 §2-3-1 幾何優化 16 §2-3-2 點能量(Single point energy) 17 §2-3-3 Geometric combining rules 17 §2-3-4 VASP計算軟體 17 §2-3-4-1 擾動彈簧模型(Nudged Elastic Band; NEB) 18 §2-3-4-2 功函數(Work function) 20 §2-3-4-3電子局域化函數(Electron localization function, ELF) 21 §2-3-5 Lammps 22 §2-3-5-1 Optimized Potentials for Liquid Simulations force field 22 §2-3-6 分子動力學模擬 22 §2-3-6-1 Nosé-Hoover恆溫器 23 §2-3-6-2 Langevin恆溫器 23 §2-3-6-3 Ewald summation 23 第三章 結果與討論 25 一、 CU(711) 階梯表面探討 25 二、 CO 在 CU(711) 階梯表面上的活性位 28 三、 CO 在 CU(711) 階梯表面上的質子化反應 36 四、 CO在 CU(711) 階梯表面上的二聚化反應 37 I. *CO + *COH → *OCCOH 38 II. *CO + *CO → *OCCO 40 總結 45 參考文獻 46

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