Green hydrocarbon-range production via catalytic pyrolysis of oleic acid over MgO regulated NiO/SiO2 catalysts

Selective catalytic deoxygenation of fatty acids has been recognized as a promising approach for producing sustainable fuels. However, limited catalytic activity often results in reduced selectivity for desired products. Herein, a series of MgO-promoted NiO/SiO2 catalysts featuring Mg-decorated NiO...

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Published in:Journal of analytical and applied pyrolysis 2025-03, Vol.186, p.106913, Article 106913
Main Authors: Fu, Meihua, Zhang, Shengzu, Wang, Jida, Shi, Feng, Chen, Yifei, Chengguo, Liu, Yang, Shunxiong, Hou, Defa, Lu, Yi, Yang, Fulin, Liu, Can, Lin, Xu, Zheng, Zhifeng, Zheng, Yunwu
Format: Article
Language:English
Subjects:
Catalytic pyrolysis
Gasoline-rich fractions
Mg-Ni bimetallic catalyst
Selective deoxygenation
Synergistic mechanism
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Summary:Selective catalytic deoxygenation of fatty acids has been recognized as a promising approach for producing sustainable fuels. However, limited catalytic activity often results in reduced selectivity for desired products. Herein, a series of MgO-promoted NiO/SiO2 catalysts featuring Mg-decorated NiO interfaces was synthesized for oleic acid catalytic deoxygenation to gasoline-range hydrocarbon. Detailed characterization and experiment revealed that Ni0 species was the active phase which could provide active H atom to enhance C-C bond cracking and hydrodeoxygenation via dissociation H2, and Mg species introduction significant promoted NiOx species well-dispersion and enhanced oxygen vacancies content to adsorption and activate carbonyl group. Notably, 3 %-Mg promoted Ni-SiO2 catalyst exhibited superior catalytic activity with 100 % conversion rate, 96.83 % and 54.58 % yield of hydrocarbon compound and olefins yield and 70.25 % selectivity to gasoline-range fraction via dehydration-hydrogenation process due to excellent acidity site, oxygen vacancies, texture properties and well-distribution and synergistic promoting effect of Ni and Mg species. Furthermore, coke deposition, active species reduction and leaching was reasonable for catalyst deactivation, resulting in hydrocarbon yield and olefin selectivity decreasing after five cycling. This deep understanding provided a facile strategy for catalyst rational design and the developed Mg/Ni-Si catalysts highlighted a great prospect for produce green hydrocarbon-rich fuel from biomass-derived oxygen-containing compound. [Display omitted] •MgO modified Ni/SiO2 catalysts were evaluated for selective hydrogenation of OA to HCs.•MgO partly covers metallic Ni, forming an MgO/Ni interface.•High selectivity of hydrocarbons (96.83 %) and olefins (70.25 %) were obtained.•The relationship between catalyst structure and activity was evaluated.•Synergistic effect between MgO and NiOx facilitated to hydrocarbon-range formation.
ISSN:0165-2370
DOI:10.1016/j.jaap.2024.106913