Highly efficient catalytic hydrocracking of East Inner Mongolia lignite and lignite-related model compounds through selective cleavage of aryl C-O bonds

IF 5.8 2区 化学 Q1 CHEMISTRY, ANALYTICAL
Han-Bing Gao , Yue-Lun Wang , Chen-Xiao Wang , Mei-Yue Huang , Le-Le Qiu , Jing Liang , Fang-Jing Liu , Jian Li , Jing-Pei Cao , Yun-Peng Zhao
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Abstract

Highly efficient catalytic hydrocracking of lignite through selective cleavage of aryl C-O bonds to produce valuable fuels and chemicals is a prospective but challenging approach. Catalytic hydrocracking reactions of lignite and lignite-related model compounds were performed over a Ni-based catalyst. The results demonstrated that the aryl C-O bonds in benzyl phenyl ether and dinaphthyl ether were preferentially cleaved and the resulting aromatic monomers were subsequently hydrogenated with continuous optimization of reaction conditions. Moreover, a complete conversion of model compounds and 100 % selectivity of monomeric products were achieved. The density functional theory calculations unraveled that the stable horizontal adsorption of both benzene rings in benzyl phenyl ether at Ni sites can reduce the electron cloud density around ether-oxygen bonds and weaken their dissociation energy, facilitating the dominant cleavage of aryl C-O bonds. Component analyses and structural characterizations indicated that aromatic hydrocarbons were mainly produced (50.02 %) after catalytic hydrocracking of lignite through the selective cleavage of C-O bonds, effective removal of oxygen-containing structure and cracking of side chain groups on aromatic rings. Most significantly, this study proposed the probable mechanism that H+ species originating from the heterolytic cleavage of H2 and H···H were the main active hydrogen species, committing to cracking C-O bonds, while H···H species were tendentious for subsequent hydrogenation of aromatic rings.
通过选择性裂解芳基 C-O 键高效催化内蒙古东部褐煤和褐煤相关模型化合物的加氢裂化
通过选择性裂解芳基 C-O 键对褐煤进行高效催化加氢裂化以生产有价值的燃料和化学品是一种前景广阔但极具挑战性的方法。研究人员在镍基催化剂上进行了褐煤和褐煤相关模型化合物的催化加氢裂化反应。结果表明,随着反应条件的不断优化,苄基苯基醚和二萘醚中的芳基 C-O 键被优先裂解,随后生成的芳香族单体被氢化。此外,还实现了模型化合物的完全转化和单体产物的 100% 选择性。密度泛函理论计算表明,苄基苯基醚中的两个苯环稳定地水平吸附在镍位点上,可以降低醚氧键周围的电子云密度,减弱其解离能,从而促进芳基 C-O 键的裂解。成分分析和结构表征表明,通过选择性裂解 C-O 键、有效去除含氧结构和裂解芳香环上的侧链基团,催化褐煤加氢裂化后主要产生了芳香烃(50.02%)。最重要的是,该研究提出了一种可能的机理,即 H2 和 H---H 的异解裂解产生的 H+ 物种是主要的活性氢物种,致力于裂解 C-O 键,而 H---H 物种则倾向于随后的芳香环氢化。
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来源期刊
CiteScore
9.10
自引率
11.70%
发文量
340
审稿时长
44 days
期刊介绍: The Journal of Analytical and Applied Pyrolysis (JAAP) is devoted to the publication of papers dealing with innovative applications of pyrolysis processes, the characterization of products related to pyrolysis reactions, and investigations of reaction mechanism. To be considered by JAAP, a manuscript should present significant progress in these topics. The novelty must be satisfactorily argued in the cover letter. A manuscript with a cover letter to the editor not addressing the novelty is likely to be rejected without review.
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