Martin Holeňa scite author profile

A database consisting of 1870 data sets on catalyst compositions and their performances in the oxidative coupling of methane was compiled. For this goal, about 1000 full-text references from the last 30 years have been analyzed and about 420 of them, which contained all the necessary information, were selected for the data extraction. The accumulated data were subject to statistical analysis: analysis of variance, correlation analysis, and decision tree. On the basis of the results, 18 catalytic key elements were selected from originally 68 elements. All oxides of the selected elements, which positively affect the selectivity to C2 products, show strong basicity. Analysis of binary and ternary interactions between the selected key elements shows that high-performance catalysts are mainly based on Mg and La oxides. Alkali (Cs, Na) and alkalineearth (Sr, Ba) metals used as dopants increase the selectivity of the host oxides, whereas dopants such as Mn, W, and the Cl anion have positive effects on the catalyst activity. The maximal C2 selectivities for the proposed catalyst compositions range from 72 to 82%, and the respective C2 yields range from 16 to 26%

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Catalyst Development for CO₂ Hydrogenation to Fuels

Rodemerck

Holeňa

Wagner³

et al. 2013

ChemCatChem

169

115

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New active and selective catalyst compositions for the hydrogenation of CO2 to mainly fuel‐type higher hydrocarbons were developed by application of an evolutionary strategy. It was shown that Fe and K supported on TiO2 and modified by Cu plus other modifiers resulted in highest selectivity for C5–C15 hydrocarbons at high degrees of CO2 conversion. Co containing catalysts were less suited since they produced methane and light hydrocarbons with high selectivities. A detailed study of reaction conditions showed that selected catalyst compositions were able to reach high CO2 conversion with still low selectivities to methane at higher reaction temperatures and a higher H2/CO2 ratio.

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Application of a genetic algorithm and a neural network for the discovery and optimization of new solid catalytic materials

Rodemerck

Baerns

Holeňa

et al. 2004

Applied Surface Science

114

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Martin Holeňa

Statistical Analysis of Past Catalytic Data on Oxidative Methane Coupling for New Insights into the Composition of High‐Performance Catalysts

Catalyst Development for CO₂ Hydrogenation to Fuels

Application of a genetic algorithm and a neural network for the discovery and optimization of new solid catalytic materials

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Martin Holeňa

Statistical Analysis of Past Catalytic Data on Oxidative Methane Coupling for New Insights into the Composition of High‐Performance Catalysts

Catalyst Development for CO2 Hydrogenation to Fuels

Application of a genetic algorithm and a neural network for the discovery and optimization of new solid catalytic materials

Contact Info

Product

Resources

About

Catalyst Development for CO₂ Hydrogenation to Fuels