On the Synthesis of Molybdenum Carbide With Cobalt Addition via Gas-Solid Reactions in a Ch4/H2 Atmosphere

Araújo, Camila Pacelly Brandão de; Souza, Carlson Pereira de; Maia, L. M. D.; Souto, Maria Veronilda Macedo; Barbosa, Cleonilson Mafra

doi:10.1590/0104-6632.20160333s20150107

Cited by 7 publications

(4 citation statements)

References 31 publications

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“…The catalyst was then carburized with a process shown in previous literature. 33,34 The catalyst was carburized on a stainless steel reactor with a capacity for 10 g of catalyst. During the carburization, a flow of 250 ml/min of a mixture containing 20% CH 4 in H 2 was passed through the reactor.…”

Section: Introductionmentioning

confidence: 99%

Effects of reaction parameters on the deoxygenation of soybean oil for the sustainable production of hydrocarbons

Pimenta

Barreto

Santos

et al. 2020

Env Prog and Sustain Energy

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Hydrotreating of vegetable oils offers a green alternative to oil‐derived fuels and raw hydrocarbon materials, usually obtained from oil. In contrast to sulfided catalysts, which contaminate the product with sulfur, carbide‐based catalysts are able to produce clean hydrocarbons. A NiMo carbide‐based catalyst, supported on nanometric γ‐alumina was prepared, characterized by X‐ray crystallography, Nitrogen physisorption, scanning electron microscopy, energy‐dispersive X‐ray spectroscopy, and Raman spectroscopy. The oxidation temperatures and acidity were also determined. Tests were performed in a batch‐type reactor for the hydrotreatment of soybean oil at 360, 380, and 400°C and 4.5 MPa. Liquid samples were analyzed by gas chromatography with a mass spectra detector. The reaction rate was calculated showing that reactant concentration did not influence deoxygenation rates, nor did the catalyst revealed a significant change in the activity. The product composition was extensively characterized, proving that reaction temperature greatly influences the concentration of aromatic, unsaturated and saturated hydrocarbons, as well as chain size distributions.

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Section: Introductionmentioning

confidence: 99%

Effects of reaction parameters on the deoxygenation of soybean oil for the sustainable production of hydrocarbons

Pimenta

Barreto

Santos

et al. 2020

Env Prog and Sustain Energy

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“…Wang et al [17] reported that the highest diffraction peak of α-MoO3 appears at 2θ = 27.36°; meanwhile, Sen et al [18] reported that it appears at 2θ = 27.32°. Moreover, new peaks appear at 2θ = 26.5, 27.3, 28.2, 32.2, and 33.8° in the Co-Mo/ZSM-5 catalyst, corresponding to β-CoMoO4 (JCPDS-21-0868) [20][21][22][23]. Based on this analysis, it can be deduced that the metals have been impregnated with the ZSM-5 catalyst due to the appearance of the peaks corresponding to the impregnated metals.…”

Section: Catalysts Characterizationsmentioning

confidence: 80%

“…On the other hand, the peak at 2θ = 27.6 • in ZSM-5 is sharpened/heightened and shifted to 27.4 • due to the presence of the highest corresponding peak of α-MoO 3 . Wang et al [17] reported that the highest diffraction peak of α-MoO 3 appears at 2θ = 27.36 • ; meanwhile, Sen et al [18] reported that it appears at 2θ = 27.32 [20][21][22][23]. Based on this analysis, it can be deduced that the metals have been impregnated with the ZSM-5 catalyst due to the appearance of the peaks corresponding to the impregnated metals.…”

Section: Catalysts Characterizationsmentioning

confidence: 88%

Improved Brønsted to Lewis (B/L) Ratio of Co- and Mo-Impregnated ZSM-5 Catalysts for Palm Oil Conversion to Hydrocarbon-Rich Biofuels

et al. 2021

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The purposes of this study are to investigate the effect of metal (Co and Mo) impregnation to ZSM-5 catalysts on the Brønsted to Lewis (B/L) ratio as the active sites of cracking reaction, and the catalysts’ performance testing for palm oil cracking to produce hydrocarbon-rich biofuels. Both metals were impregnated on the ZSM-5 catalyst using a wet-impregnation method. The catalysts were characterized using X-ray diffraction (XRD), X-ray Fluorescence (XRF), Scanning Electron Microscopy (SEM), Brunauer–Emmett–Teller (BET), and Pyridine-probed Fourier-Transform Infrared (Py-FTIR) spectroscopy methods. The catalysts were tested on the cracking process of palm oil to biofuels in a continuous fixed-bed catalytic reactor. In order to determine the composition of the organic liquid product (OLP, biofuels), the product was analyzed using a gas chromatography-mass spectrometry (GC-MS) method. The results showed that the co-impregnation of Co and Mo to ZSM-5 highly increased the Brønsted to Lewis acid site (B/L) ratio, although the total number of acid sites decreased. However, the impregnation of Co and Mo on the ZSM-5 decreased the surface area of catalysts due to pore blocking by metals, while the B/L ratio of the catalysts increased. It was obtained that by utilizing Co- and Mo-impregnated ZSM-5 catalysts, the hydrocarbons product selectivity increased from 84.32% to 95.26%; however, the yield of biofuels decreased from 67.57% to 41.35%. The increase in hydrocarbons product selectivity was caused by the improvement of the Brønsted to Lewis (B/L) acid sites ratio.

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“…Mo 2 C/CNF catalyst also showed a major reflexion intensity at 26 • and a minor peak at 45 • , with both being assigned to the graphitic carbon phase. The same diffractograms also revealed seven small peaks assigned to the molybdenum carbide phase (Mo 2 C), with reflexions detected at 2θ angles of 34 • , 38 • , 40 • , 52 • , 61 • , 69 • , 75 • , and 76 • , assigned to orthorhombic Mo 2 C (lattice parameters a = 0.4724 nm, b = 0.6002 nm, c = 0.5215 nm) [11,[29][30][31][32][33]. The size of the crystallites (interpreted here as coherent diffraction domains) estimated by XRD is ca.…”

Section: Fresh Catalysts Characterizationmentioning

confidence: 99%

Liquid-Phase Hydrodeoxygenation of Guaiacol over Mo2C Supported on Commercial CNF. Effects of Operating Conditions on Conversion and Product Selectivity

et al. 2018

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In this work, a Mo 2 C catalyst that was supported on commercial carbon nanofibers (CNF) was synthetized and tested in the hydrodeoxygenation (HDO) of guaiacol. The effects of operating conditions (temperature and pressure) and reaction time (2 and 4 h) on the conversion of guaiacol and products selectivity were studied. The major reaction products were cresol and phenol, followed by xylenols and toluene. The use of more severe operating conditions during the HDO of guaiacol caused a diversification in the reaction pathways, and consequently in the selectivity to products. The formation of phenol may have occurred by demethylation of guaiacol, followed by dehydroxylation of catechol, together with other reaction pathways, including direct guaiacol demethoxylation, and demethylation of cresols. X-ray diffraction (XRD) analysis of spent catalysts did not reveal any significant changes as compared to the fresh catalyst.

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On the Synthesis of Molybdenum Carbide With Cobalt Addition via Gas-Solid Reactions in a Ch4/H2 Atmosphere

Cited by 7 publications

References 31 publications

Effects of reaction parameters on the deoxygenation of soybean oil for the sustainable production of hydrocarbons

Effects of reaction parameters on the deoxygenation of soybean oil for the sustainable production of hydrocarbons

Improved Brønsted to Lewis (B/L) Ratio of Co- and Mo-Impregnated ZSM-5 Catalysts for Palm Oil Conversion to Hydrocarbon-Rich Biofuels

Liquid-Phase Hydrodeoxygenation of Guaiacol over Mo2C Supported on Commercial CNF. Effects of Operating Conditions on Conversion and Product Selectivity

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