Kinetic modelling of the catalytic conversion of synthesis gas

Simard, François; Mahay, A.; Jean, G; deLasa, Hugo

doi:10.1002/cjce.5450690412

Cited by 8 publications

(2 citation statements)

References 19 publications

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“…In comparison with the Co‐based catalysts, Fe or other methanol synthesis catalysts are more favored for the production of aromatic monomers from syngas, although both catalysts have their own advantages and disadvantages. For example, WGS activity is quite problematic on those traditional methanol synthesis catalysts such as Cr–Zn, Pd–Zn, and Cu–Zn metal oxides as a result of an ample amount of CO 2 production in the range of ≈40−75 wt%, and hence very lower hydrocarbon formation (≈25 wt%) . Compared to the Cu–Zn and Pd‐based bifunctional catalysts, the Cr–Zn/HZSM‐5 or Zn–ZrO 2 /HZSM‐5 can transform completely the formed intermediates (oxygenates) to aromatics, which seems to be attributed to a combined acidic site effect of the HZSM‐5 and metal oxides (slightly acidic nature).…”

Section: Conversions Of Syngas (Co+h2) Into Aromaticsmentioning

confidence: 99%

Recent Advances in Direct Synthesis of Value‐Added Aromatic Chemicals from Syngas by Cascade Reactions over Bifunctional Catalysts

2019

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Value‐added aromatic monomers such as benzene, toluene, and xylenes (BTX) are very important building‐block chemicals for the production of plastics, polymers, solvents, pesticides, dyes, and adhesives. Syngas‐to‐aromatics (STA) is a very promising approach for the synthesis of aromatic monomers, and is catalyzed via bifunctional catalysts in a single reactor, wherein methanol/dimethyl ether and/or olefins intermediates formed from syngas on metal components are converted into aromatic monomers exclusively on the HZSM‐5 by cascade reactions. Since an optimal Fischer–Tropsch synthesis (FTS) temperature of Fe‐based catalysts is very close to an aromatization temperature of HZSM‐5, Fe‐based catalysts have been frequently used/modified for the synthesis of aromatic monomers from hydrogenation of carbon oxides (CO and CO2). The nature of metal components and amounts of Brönsted acid sites on HZSM‐5, and their mesoporosity and intimacy, significantly alter the selectivity for aromatics by tuning BTX distibution and catalyst stability. Although many developments have been achieved regarding the STA process in recent years, no reviews have been published in this flourishing research area over the last two decades. Here, the recent advances and forthcoming challenges in the progress of syngas (CO+H2) chemistry and hydrogenation of CO2 toward the value‐added aromatic monomers through cascade reactions are highlighted.

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Section: Conversions Of Syngas (Co+h2) Into Aromaticsmentioning

confidence: 99%

Recent Advances in Direct Synthesis of Value‐Added Aromatic Chemicals from Syngas by Cascade Reactions over Bifunctional Catalysts

2019

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“…The present research is also a valuable complement to several studies initiated in 1987 and continued in recent years at the CREC Laboratories, The University of Western Ontario, by Hugo de Lasa’s research group. Examples of these successful studies include methanol conversion to gasoline, − syngas conversion to liquid hydrocarbons, − and desulfurization of gasoline. ,− …”

Section: Introductionmentioning

confidence: 99%

HZSM-5 Zeolites with Different SiO₂/Al₂O₃Ratios. Characterization and NH₃Desorption Kinetics

Al-Dughaither

Lasa

2014

Ind. Eng. Chem. Res.

264

129

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This article reports the influence of the SiO2/Al2O3 ratio (30, 80, and 280) on HZSM-5 zeolite properties. XRD patterns show a decrease in the XRD peak intensity at low 2θ angles for low SiO2/Al2O3 ratio zeolites. N2 adsorption and desorption isotherms display hysteresis with both micropores and mesopores likely contributing to the particles network. The NLDFT cylindrical model confirms the characteristic 5.5 Å micropores in the zeolite pore framework. Furthermore, specific surface area, pore volume, and pore size distributions demonstrate that changes in the SiO2/Al2O3 ratio do not influence HZSM-5 structural properties. NH3-TPD shows both weak and strong acid sites. Pyridine-FTIR also confirms that, in HZSM-5, the weak acidity encompasses Lewis and hydrogen-bonded sites, while the strong acidity mainly involves the Brönsted acid sites. It is proven that the ratio of weak to strong acid sites as measured by NH3-TPD and Pyridine-FTIR displays similar changes to the SiO2/Al2O3 ratio. Furthermore, NH3 desorption kinetics and numerical regression allow the establishment of energies of activation for both strong and weak acid sites. It is also found that the kinetic desorption rate constants vary in agreement with the changes in weak and strong acid sites as observed with NH3-TPD and Pyridine-FTIR.

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Compound catalyst for high yields of olefins from synthesis gas

Lasa

Hagey

Rong

et al. 1996

Chemical Engineering Science

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Kinetic modelling of the catalytic conversion of synthesis gas

Cited by 8 publications

References 19 publications

Recent Advances in Direct Synthesis of Value‐Added Aromatic Chemicals from Syngas by Cascade Reactions over Bifunctional Catalysts

Recent Advances in Direct Synthesis of Value‐Added Aromatic Chemicals from Syngas by Cascade Reactions over Bifunctional Catalysts

HZSM-5 Zeolites with Different SiO₂/Al₂O₃Ratios. Characterization and NH₃Desorption Kinetics

Compound catalyst for high yields of olefins from synthesis gas

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Kinetic modelling of the catalytic conversion of synthesis gas

Cited by 8 publications

References 19 publications

Recent Advances in Direct Synthesis of Value‐Added Aromatic Chemicals from Syngas by Cascade Reactions over Bifunctional Catalysts

Recent Advances in Direct Synthesis of Value‐Added Aromatic Chemicals from Syngas by Cascade Reactions over Bifunctional Catalysts

HZSM-5 Zeolites with Different SiO2/Al2O3Ratios. Characterization and NH3Desorption Kinetics

Compound catalyst for high yields of olefins from synthesis gas

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Product

Resources

About

HZSM-5 Zeolites with Different SiO₂/Al₂O₃Ratios. Characterization and NH₃Desorption Kinetics