Effect of potassium in catalysts obtained by the solution combustion synthesis for co-production of hydrogen and carbon nanofibers by catalytic decomposition of methane

Chudakova, M.V.; Popov, M.V.; Korovchenko, P.A.; Pentsak, E.O.; Latypova, A.R.; Kurmashov, P.B.; Pimenov, A.A.; Tsilimbaeva, E.A.; Levin, I.S.; Bannov, A.G.; Kleymenov, A.V.

doi:10.1016/j.ces.2023.119408

Cited by 7 publications

(2 citation statements)

References 56 publications

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“…This shift led to increased H 2 yields. The Ni-0.25%K 2 O/Al 2 O 3 and Ni-1%K 2 O/Al 2 O 3 catalysts had the highest hydro-gen yields of 11.6 g/gcat and 17.0 g/gcat, respectively, and the Ni-1%K 2 O/Al 2 O 3 catalyst produced the best carbon material yield (51.0 g/gcat) [39]. In order to study the process of producing hydrogen in situ from the conversion of shale gas (methane) using microwave heating of a methane stream passing through a filled shale sample, Yan et al carried out a number of tests.…”

Section: Catalytic Materials For Hydrogen From Methane Decompositionmentioning

confidence: 99%

Materials Enabling Methane and Toluene Gas Treatment

Lv,

Wang

2024

Materials

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This paper summarizes the latest research results on materials for the treatment of methane, an important greenhouse gas, and toluene, a volatile organic compound gas, as well as the utilization of these resources over the past two years. These materials include adsorption materials, catalytic oxidation materials, hydrogen-reforming catalytic materials and non-oxidative coupling catalytic materials for methane, and adsorption materials, catalytic oxidation materials, chemical cycle reforming catalytic materials, and degradation catalytic materials for toluene. This paper provides a comprehensive review of these research results from a general point of view and provides an outlook on the treatment of these two gases and materials for resource utilization.

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Section: Catalytic Materials For Hydrogen From Methane Decompositionmentioning

confidence: 99%

Materials Enabling Methane and Toluene Gas Treatment

Lv,

Wang

2024

Materials

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“…The combustion reaction is considered a relatively simple, effective, and low-cost technique, widely established in the literature as a procedure used for the synthesis of various types of oxides [15][16][17] with applications in the production of biodiesel [18]. The innovative aspect of this work is in the consolidation of MoO 3 catalysts obtained through the combustion reaction, offering a significant contribution to studies on the optimization of the biofuel production process.…”

Section: Introductionmentioning

confidence: 99%

Optimization of Biodiesel Production Process Using MoO3 Catalysts and Residual Oil: A Comprehensive Experimental 23 Study

Silva,

Pereira,

Sales

et al. 2024

Molecules

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The study aimed to utilize MoO3 catalysts, produced on a pilot scale via combustion reaction, to produce biodiesel from residual oil. Optimization of the process was conducted using a 23 experimental design. Structural characterization of the catalysts was performed through X-ray diffraction, fluorescence, Raman spectroscopy, and particle size distribution analyses. At the same time, thermal properties were examined via thermogravimetry and differential thermal analysis. Catalytic performance was assessed following process optimization. α-MoO3 exhibited a monophasic structure with orthorhombic phase, whereas α/h-MoO3 showed a biphasic structure. α-MoO3 had a larger crystallite size and higher crystallinity, with thermal stability observed up to certain temperatures. X-ray fluorescence confirmed molybdenum oxide predominance in the catalysts, with traces of iron oxide. Particle size distribution analyses revealed polymodal distributions attributed to structural differences. Both catalysts demonstrated activity under all conditions tested, with ester conversions ranging from 93% to 99%. The single-phase catalyst had a long life cycle and was reusable for six biodiesel production cycles. The experimental design proved to be predictive and significant, with the type of catalyst being the most influential variable. Optimal conditions included α-MoO3 catalyst, oil/alcohol ratio of 1/15, and a reaction time of 60 min, resulting in high biodiesel conversion rates and showcasing the viability of MoO3 catalysts in residual oil biodiesel production.

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Kinetics of the CH4/O2 reaction over supported palladium catalysts on K-doped manganite perovskite: Impact of potassium on the nature of Pd-support interface and related reaction mechanisms

Zheng,

Granger

2024

Applied Surface Science

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Effect of potassium in catalysts obtained by the solution combustion synthesis for co-production of hydrogen and carbon nanofibers by catalytic decomposition of methane

Cited by 7 publications

References 56 publications

Materials Enabling Methane and Toluene Gas Treatment

Materials Enabling Methane and Toluene Gas Treatment

Optimization of Biodiesel Production Process Using MoO3 Catalysts and Residual Oil: A Comprehensive Experimental 23 Study

Kinetics of the CH4/O2 reaction over supported palladium catalysts on K-doped manganite perovskite: Impact of potassium on the nature of Pd-support interface and related reaction mechanisms

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