铜催化剂氢化草酸二甲酯过程中副产物 1,2-丙二醇形成机理的 DFT 研究

Q3 Energy 燃料化学学报 Pub Date : 2024-04-01 DOI:10.1016/S1872-5813(23)60399-8
Guodong LUN , Weiqi AN , Jinghong ZHOU , Yi'an ZHU , I Wei
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引用次数: 0

摘要

1,2-丙二醇(1,2-PDO)是草酸二甲酯(DMO)加氢过程中不可避免的副产物,其昂贵的分离成本严重影响了煤制乙二醇(EG)技术的经济可行性。为解决这一难题,研究人员通过密度泛函理论计算,重点研究了 DMO 加氢过程中副产物 1,2-PDO 在 Cu(111) 和 Cu2O(111) 表面的形成机理,包括铜催化剂的活性位点和主导途径。系统分析了各基本步骤的热力学、反应网络中各种物质的吸附行为以及局部态密度和电荷密度差。结果表明,1,2-PDO 在 Cu2O(111) 表面比在 Cu(111) 表面更容易生成,原因是 Cu2O(111) 表面存在路易斯酸碱对,即 Cu+ us 和 O- suf 位点,这加强了反应物、产物和反应中间产物与底物的结合。EG 主要与甲醇(MeOH)反应,通过 Guerbet 醇缩合反应生成 1,2-PDO,反应连续经过三个步骤:醇脱氢、醛缩合和不饱和醛加氢。O- suf 位点促进醇脱氢成醛、醛缩合过程中生成烯醇以及不饱和醛的氢化,而 Cu+ us 位点则负责 C-C 偶联反应。这些发现可能揭示了在铜催化剂上形成 1,2-PDO 的机理,并为开发更高效的催化剂和优化工艺提供了基础知识。
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A DFT study on the formation mechanism of side product 1,2-propanediol in the hydrogenation of dimethyl oxalate over copper catalyst

The costly separation of 1,2-propanediol (1,2-PDO), an unavoidable byproduct in the hydrogenation of dimethyl oxalate (DMO), significantly hampers the economic viability of coal-to-ethylene glycol (EG) technology. To address this challenge, the formation mechanism of the side product 1,2-PDO on the Cu(111) and Cu2O(111) surfaces during DMO hydrogenation was investigated, which focused on the active sites of copper catalyst and the dominant pathway through density functional theory calculation. The thermodynamics of each elementary step and the adsorption behavior of various species involved in the reaction network along with the local density of states and charge density difference were systematically analyzed. The results indicate that 1,2-PDO is generated more favorably on the Cu2O(111) surface than that on the Cu(111) surface, owing to the Lewis acid-base pairs, i.e. Cu+ us and O– suf sites, present on the Cu2O(111) surface, which strengthens the binding of reactants, products, and reaction intermediates to the substrate. EG reacts primarily with methanol (MeOH) to form 1,2-PDO through Guerbet alcohol condensation reaction through three consecutive steps: alcohol dehydrogenation, aldol condensation, and unsaturated aldehyde hydrogenation. The O– suf sites promote the dehydrogenation of alcohols into aldehydes, the generation of enolates during aldol condensation and the hydrogenation of unsaturated aldehydes, while the Cu+ us sites are responsible for the C–C coupling reaction. These findings may shed light on the mechanism of 1,2-PDO formation over Cu catalyst and provide fundamental knowledge for the development of more efficient catalysts and process optimization.

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来源期刊
燃料化学学报
燃料化学学报 Chemical Engineering-Chemical Engineering (all)
CiteScore
2.80
自引率
0.00%
发文量
5825
期刊介绍: Journal of Fuel Chemistry and Technology (Ranliao Huaxue Xuebao) is a Chinese Academy of Sciences(CAS) journal started in 1956, sponsored by the Chinese Chemical Society and the Institute of Coal Chemistry, Chinese Academy of Sciences(CAS). The journal is published bimonthly by Science Press in China and widely distributed in about 20 countries. Journal of Fuel Chemistry and Technology publishes reports of both basic and applied research in the chemistry and chemical engineering of many energy sources, including that involved in the nature, processing and utilization of coal, petroleum, oil shale, natural gas, biomass and synfuels, as well as related subjects of increasing interest such as C1 chemistry, pollutions control and new catalytic materials. Types of publications include original research articles, short communications, research notes and reviews. Both domestic and international contributors are welcome. Manuscripts written in Chinese or English will be accepted. Additional English titles, abstracts and key words should be included in Chinese manuscripts. All manuscripts are subject to critical review by the editorial committee, which is composed of about 10 foreign and 50 Chinese experts in fuel science. Journal of Fuel Chemistry and Technology has been a source of primary research work in fuel chemistry as a Chinese core scientific periodical.
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