The relationship between the microstructures and catalytic behaviors of iron–oxygen precursors during direct coal liquefaction

Xie, Jing; Lu, Hanfeng; Shu, Geping; Li, Kejian; Zhang, Xuwen; Wang, Hongxue; Wang, Yue; Gao, Shansong; Chen, Yinfei

doi:10.1016/s1872-2067(17)62919-x

Cited by 13 publications

(3 citation statements)

References 28 publications

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“…Currently, iron-based catalysts are widely used due to their simple production methods, low prices, and no need for recovery. FeOOH has a high specific surface area, stable physicochemical properties, and special particle structure, which can be easily transformed into iron sulfide with a small particle size, excellent catalytic activity, and good stability. , Traditional methods of FeOOH preparation mainly include room-temperature solid-phase method, aniline method, hydrothermal method, sol–gel method, chemical precipitation method, air oxidation method, and mechanical-force solid-phase method . The advantages of the mechanical-force solid-phase method for the preparation of FeOOH are mild reaction conditions, high yield, no solvent, simple process, and low-energy consumption.…”

Section: Introductionmentioning

confidence: 99%

Preparation of Iron-Based Catalysts by Mechanical Solid-Phase Ball Milling and Their Applications in Cohydrogenation of Coal and Petrochemical Coking Residual Oil

Sun

Huang

et al. 2023

ACS Omega

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Catalysts are an important factor in reducing harsh reaction conditions and increasing oil yields for the cohydrogenation of coal-oil. In this article, nano-iron-based catalysts have been prepared by mechanical solid-phase ball milling with FeCl 3 •6H 2 O, Fe(NO 3 ) 3 •9H 2 O, and ammonium carbonate as reactants. The catalysts were characterized by X-ray diffraction, scanning electron microscopy, and transmission electron microscopy. With these catalysts, cohydrogenation behaviors of coal-oil have been carried out with Hami Baishihu coal and Karamay petrochemical coking residual oil under conditions of 400 °C, initial pressure of 7 MPa, and reaction time of 1 h. The results showed that the coal conversion rate reached 98.45% and the oil yield reached 77.73% when the catalyst prepared with FeCl 3 •6H 2 O as an iron source was added. Compared with research results reported in the literature, under the same conditions, the catalyst prepared in this article showed better catalytic activity in the cohydrogenation of coal-petrochemical coking residual oil.

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Section: Introductionmentioning

confidence: 99%

Preparation of Iron-Based Catalysts by Mechanical Solid-Phase Ball Milling and Their Applications in Cohydrogenation of Coal and Petrochemical Coking Residual Oil

Sun

Huang

et al. 2023

ACS Omega

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“…For example, Xie et al studied the relationship between catalyst microstructure and catalytic behavior during the catalytic conversion of coal. in particular, the effects of different crystal shapes and morphologies on the catalytic activity [ 32 ]. Wang et al reported that lamellar MoS 2 was more easily inserted into macromolecules, thus improving the catalytic hydrogenation performance [ 33 ].…”

Section: Introductionmentioning

confidence: 99%

Insights into the Relationship between the Microstructure and the Catalytic Behavior of Fe2(MoO4)3 during the Ethanolysis of Naomaohu Coal

Liu,

Sun,

Tang

et al. 2023

Molecules

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Ethanolysis is an effective method to depolymerize weak bonds in lignite under mild conditions, which can result in the production of high-value-added chemicals. However, improving ethanolysis yield and regulating its resulting product distribution is a big challenge. Hence, exploiting highly active catalysts is vital. In this work, Fe2(MoO4)3 catalysts with zero-dimensional nanoparticles, one-dimensional (1D) nanorods, two-dimensional (2D) nanosheets, and three-dimensional (3D) nanoflower structures were successfully prepared and applied in the ethanolysis of Naomaohu coal. The results showed that for all samples, the yield of ethanol-soluble portions (ESP) was significantly improved. The highest yield was obtained for the Fe2(MoO4)3 nanorods, with an increase from 28.84% to 47.68%, and could be attributed to the fact that the Fe2(MoO4)3 nanorods had a higher number of exposed active (100) facets. In addition, the amounts of oxygen-containing compounds, such as ethers, esters, and phenols, increased significantly. The mechanism of ethanolysis catalyzed by the Fe2(MoO4)3 nanorods was also studied using phenylbenzyl ether (BOB) as a model compound. BOB was completely converted at 260 °C after 2 h. It is suggested that Fe2(MoO4)3 nanorods can effectively break the C-O bonds of coal macromolecules, thus promoting the conversion of coal.

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“…As more and more people are keen on developing innovative hydrogenation catalysts, the pace of progress in this area is accelerating. Low-cost and environmentally friendly Fe-based particle or supported catalysts (Kuznetsov et al 2000;Kaneko et al 2002;Sheng et al 2017;Zhou et al 2018;Xie et al 2018;Lokhat et al 2019;) have been widely studied and applied in industrial installations. Unfortunately, the mediocre hydrogenation performance of iron catalyst results in general performance in coal-oil co-processing.…”

Section: Introductionmentioning

confidence: 99%

Study on Hydrogenation Performance of Oil-Soluble Molybdenum Catalyst in Coal-Oil Co-Processing

Wang

Xiqian

Zhao

2022

Preprint

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An oil-soluble molybdenum catalyst was synthesized by a simple and novel method and studied for hydrogenation in coal-oil co-processing. The catalyst was characterized by infrared spectrum (IR), thermogravimetry (TG), X-ray diffraction (XRD) and X-ray photoelectron spectroscopy (XPS). The morphology and crystal structure of catalyst was characterized with scanning electron microscope (SEM) and high resolution transmission electron microscopy (HRTEM). The catalyst can be considered as a precursor that can be converted into active MoS2 components through thermal decomposition and sulfidation. The hydrogenation experiment was carried out by the model reactants of tetradecane and 2-methylnaphthalene with a change of reaction (405℃-445℃) temperature and concentrations of molybdenum catalyst (Mo conc. 0.6-10 mg/g), and results showed that the delightly hydrogenation function of catalyst is to improve the saturation of aromatic ring. The most abundant stacking numbers of decomposed catalyst were 2 and 3, accounting for 53% of all catalyst microcrystalline units. The rapid hydrogenation stage and the significant decrease of feed heavy fraction in co-processing experiment provided the evidence that the hydrogenation performance of the synthesized catalyst is remarkable in coal-oil co-processing.

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The relationship between the microstructures and catalytic behaviors of iron–oxygen precursors during direct coal liquefaction

Cited by 13 publications

References 28 publications

Preparation of Iron-Based Catalysts by Mechanical Solid-Phase Ball Milling and Their Applications in Cohydrogenation of Coal and Petrochemical Coking Residual Oil

Preparation of Iron-Based Catalysts by Mechanical Solid-Phase Ball Milling and Their Applications in Cohydrogenation of Coal and Petrochemical Coking Residual Oil

Insights into the Relationship between the Microstructure and the Catalytic Behavior of Fe2(MoO4)3 during the Ethanolysis of Naomaohu Coal

Study on Hydrogenation Performance of Oil-Soluble Molybdenum Catalyst in Coal-Oil Co-Processing

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