不同Rh表面上苯甲醚加氢脱氧

doi:10.1016/S1872-2067(19)63345-0

催化学报 ›› 2019, Vol. 40 ›› Issue (11): 1721-1730.DOI: 10.1016/S1872-2067(19)63345-0

不同Rh表面上苯甲醚加氢脱氧

Nhung N. Duong^a,b, Darius Aruho^a, Bin Wang^a, Daniel E. Resasco^a

a 俄克拉荷马大学化学生物和材料工程学院(CBME), 界面反应工程中心(CIRE), 诺尔曼OK 73019, 美国;
b 越南国立大学, 国际大学生物技术学院, 胡志明市 700000, 越南

收稿日期:2019-01-10 修回日期:2019-03-07 出版日期:2019-11-18 发布日期:2019-09-06
通讯作者: Bin Wang, Daniel E. Resasco
基金资助:
This work was supported by the U.S. Department of Energy, DOE/EPSCOR (Grant DESC0004600). The computational research used the supercomputer resources of the National Energy Research Scientific Computing Centre (NERSC) and the OU Supercomputing Centre for Education & Research (OSCER) at the University of Oklahoma.

Hydrodeoxygenation of anisole over different Rh surfaces

Nhung N. Duong^a,b, Darius Aruho^a, Bin Wang^a, Daniel E. Resasco^a

a School of Chemical, Biological and Materials Engineering (CBME) Center for Interfacial Reaction Engineering (CIRE) University of Oklahoma, Norman OK 73019, USA;
b School of Biotechnology, International University Vietnam National University, Ho Chi Minh City 700000, Vietnam

Received:2019-01-10 Revised:2019-03-07 Online:2019-11-18 Published:2019-09-06
Contact: Bin Wang, Daniel E. Resasco
Supported by:
This work was supported by the U.S. Department of Energy, DOE/EPSCOR (Grant DESC0004600). The computational research used the supercomputer resources of the National Energy Research Scientific Computing Centre (NERSC) and the OU Supercomputing Centre for Education & Research (OSCER) at the University of Oklahoma.

摘要/Abstract

摘要： 苯甲醚中烷氧基（Ar-O-R）醚键的断裂是一个有趣的加氢脱氧反应，因为这个不对称的基团包含两个不同的C-O键，C_aryl-O或C_alkyl O，它们可能会断裂.最近有关在铂、钌和铁催化剂上苯甲醚HDO的研究表明，在所有三种金属上都形成了一种共有的苯氧基表面中间体.该中间体的后续反应路径因金属而不同，这取决于金属的亲氧性.在亲氧性较低的铂上反应，苯酚是唯一的主要产物.相反，在亲氧性较强的铁催化剂上，唯一的初级产物是苯而不是苯酚.在亲氧性适中的Ru上，苯和苯酚都是主要产物.本文研究了不同表面纳米结构的铑催化剂.采用实验测量和理论计算相结合的方法，研究了可用来控制金属亲氧性的参数，即金属配位数的影响.结果证实了金属亲氧性是描述金属催化剂催化HDO性能的很好的指标，它可以通过选择金属类型和/或金属配位程度来加以控制.含低配位数的金属位的小Rh金属簇合物对脱氧路径活性更高，但很快失活，而含高配位数的大的簇合物对加氢活性更高，且更加稳定.

关键词: 加氢脱氧, 苯甲醚, 烷氧基, 亲氧性, 酚类, 表面缺陷

Abstract: The cleavage of the alkoxy (Ar-O-R) ether bond present in anisole is an interesting hydrodeoxygenation (HDO) reaction, since this asymmetric group contains two different C-O bonds, C_aryl-O or C_alkyl-O, which could potentially cleave. Recent work on the HDO of anisole over Pt, Ru, and Fe catalysts has shown that a common phenoxy surface intermediate is formed on all three metals. The subsequent reaction path of this intermediate varies from metal to metal, depending on the metal oxophilicity. Over the less oxophilic Pt, phenol is the only primary product. By contrast, on the more oxophilic Fe catalyst, the sole primary product is benzene instead of phenol. On Ru, with intermediate oxophilicity, both benzene and phenol are primary products. In this contribution, we have investigated Rh catalysts of varying surface nanostructures. A combination of experimental measurements and computational calculations was used to explore the effects of varying metal coordination number, an additional parameter that can be used to control the oxophilicity of a metal. The results confirm that metal oxophilicity is a good descriptor for HDO performance of metal catalysts and it can be controlled via selection of metal type and/or metal extent of coordination. Small Rh metal clusters with low coordination metal sites are more active for the deoxygenation pathway but also quickly deactivated while large clusters with high coordination sites are more active toward hydrogenation and more stable.

Key words: Hydrodeoxygenation, Anisole, Alkoxy, Oxophilicity, Phenolic, Surface defects

Nhung N. Duong, Darius Aruho, Bin Wang, Daniel E. Resasco. 不同Rh表面上苯甲醚加氢脱氧[J]. 催化学报, 2019, 40(11): 1721-1730.

Nhung N. Duong, Darius Aruho, Bin Wang, Daniel E. Resasco. Hydrodeoxygenation of anisole over different Rh surfaces[J]. Chinese Journal of Catalysis, 2019, 40(11): 1721-1730.

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不同Rh表面上苯甲醚加氢脱氧

Hydrodeoxygenation of anisole over different Rh surfaces

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