Oxidative Dehydrogenation of Ethanol over Vanadium- and Molybdenum-modified Mg-Al Mixed Oxide Derived from Hydrotalcite

Pinthong, Piriya; Praserthdam, Piyasan; Jongsomjit, Bunjerd

doi:10.5650/jos.ess19035

Cited by 8 publications

(3 citation statements)

References 34 publications

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“…An important topic with respect to catalysts for ethanol dehydrogenation is the significant deactivation that occurs due to coke formation on the catalyst surface and the sintering of the active catalyst particles. This was found in the case of PdZn nanoparticles [28], monometallic Cu [29,30], bi-or tri-metallic Cu alloys [29,[31][32][33], SiO 2 − supported Cu catalysts [34] and V/Mg − Al catalysts [35,36]. There is a considerable number of papers that use computational methods such as density functional theory or a combination of experimental methods and modelling tools to investigate correlations between catalyst activity and selectivity on the one hand and material characteristics such as crystal faces, monolayer coverages, etc., on the other [37][38][39][40][41].…”

Section: N2 Sorptionmentioning

confidence: 59%

Ethanol Dehydrogenation: A Reaction Path Study by Means of Temporal Analysis of Products

et al. 2020

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Conventional fossil fuels such as gasoline or diesel should be substituted in the future by environmentally-friendly alternatives in order to reduce emissions in the transport sector and thus mitigate global warming. In this regard, iso-butanol is very promising as its chemical and physical properties are very similar to those of gasoline. Therefore, ongoing research deals with the development of catalytically-supported synthesis routes to iso-butanol, starting from renewably-generated methanol. This research has already revealed that the dehydrogenation of ethanol plays an important role in the reaction sequence from methanol to iso-butanol. To improve the fundamental understanding of the ethanol dehydrogenation step, the Temporal Analysis of Products (TAP) methodology was applied to illuminate that the catalysts used, Pt/C, Ir/C and Cu/C, are very active in ethanol adsorption. H2 and acetaldehyde are formed on the catalyst surfaces, with the latter quickly decomposing into CO and CH4 under the given reaction conditions. Based on the TAP results, this paper proposes a reaction scheme for ethanol dehydrogenation and acetaldehyde decomposition on the respective catalysts. The samples are characterized by means of N2 sorption and Scanning Transmission Electron Microscopy (STEM).

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Section: N2 Sorptionmentioning

confidence: 59%

Ethanol Dehydrogenation: A Reaction Path Study by Means of Temporal Analysis of Products

et al. 2020

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“…Figure 2 shows the adsorption-desorption isotherms for MgAl-LDH and MgAlO catalysts. For both catalysts, their isotherms exhibited the hysteresis loop at high relative pressure (P/P 0 ＞0.7) indicating that both catalysts have the mesoporous structure of type IV (IUPAC) 27,28) . The BET surface area, pore volume and pore size of catalyst are listed in Table 1.…”

Section: Catalyst Characterizationmentioning

confidence: 99%

Optimal Conditions for Butanol Production from Ethanol over MgAlO Catalyst Derived from Mg-Al Layer Double Hydroxides

et al. 2022

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has four-step reaction, which involves the dehydrogenation, aldol condensation, dehydration and hydrogenation, respectively 8) .There are many types of catalyst used to convert ethanol into butanol via Guerbet reaction. For instance, the catalysts used included hydroxyapatites (HAP) 9−12) , zeolite 13) , metal oxides 14,15) , supported metal 16,17) and activated carbon catalysts 18,19) . The Guerbet reaction essentially requires both acid and basic sites on catalysts in which hydroxyapatites and metal oxides contain both acid sites. Furthermore, the structure of catalyst can alter the acid and basic site on catalysts, which can affect the catalytic properties during the conversion of ethanol to butanol. It was reported that the Mg-Al layered double hydroxides (MgAl-LDH) having double layer structure of Mg and Al metal cation, while structure between layer has anion, have played important roles in various reactions due to the bifunctional cation and anion in their structure. The MgAl-LDH can be used as a precursor to obtain MgAl mixed oxide catalysts by calcination of MgAl-LDH. Moreover, the difference in catalyst structure apparently affects properties of catalysts.

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“…It should be noted that since biomass absorbs carbon dioxide from the atmosphere for its growth, the processing of ethanol obtained from biomass does not contribute to global warming. Two gas-phase processes of ethanol conversion to acetaldehyde are known [12,13]: selective catalytic oxidation with oxygen or air and non-oxidative catalytic dehydrogenation. The non-oxidative dehydrogenation of ethanol to acetaldehyde in comparison with the oxidative dehydrogenation method has obvious advantages such as no oxidant, its partial oxidation to acetic acid and carbon dioxide, and that the resulting acetaldehyde is easily separated from the reaction by-products.…”

Section: Introductionmentioning

confidence: 99%

Comparative Study of Physicochemical Characteristics and Catalytic Activity of Copper Oxide over Synthetic Silicon Oxide and Silicon Oxide from Rice Husk in Non-Oxidative Dehydrogenation of Ethanol

et al. 2022

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The article presents the results of comparative research on the physicochemical characteristics and catalytic activity of copper oxide supported on synthetic SiO2 and SiO2 (RH) from rice husk. SiO2 (RH) is more hydrophobic compared to SiO2, which leads to the concentration of copper oxide on its surface in the form of a “crust”, which is very important in the synthesis of low-percentage catalysts. According to SEM, XRD, and TPR-H2, the use of SiO2 (RH) as a carrier leads to an increase in the dispersion of copper oxide particles, which is the active center of ethanol dehydrogenation.

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Oxidative Dehydrogenation of Ethanol over Vanadium- and Molybdenum-modified Mg-Al Mixed Oxide Derived from Hydrotalcite

Cited by 8 publications

References 34 publications

Ethanol Dehydrogenation: A Reaction Path Study by Means of Temporal Analysis of Products

Ethanol Dehydrogenation: A Reaction Path Study by Means of Temporal Analysis of Products

Optimal Conditions for Butanol Production from Ethanol over MgAlO Catalyst Derived from Mg-Al Layer Double Hydroxides

Comparative Study of Physicochemical Characteristics and Catalytic Activity of Copper Oxide over Synthetic Silicon Oxide and Silicon Oxide from Rice Husk in Non-Oxidative Dehydrogenation of Ethanol

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