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X-ray Absorption Fine StructureBuilding
The stability and reactivity of ϵ, χ, and θ iron carbide phases in Fischer−Tropsch synthesis (FTS) catalysts as a function of relevant reaction conditions was investigated by a synergistic combination of experimental and theoretical methods. Combined in situ X-ray Absorption Fine Structure Spectroscopy/X-ray Diffraction/Raman Spectroscopy was applied to study Fe-based catalysts during pretreatment and, for the first time, at relevant high pressure Fischer−Tropsch synthesis conditions, while Density Functional Theory calculations formed a fundamental basis for understanding the influence of pretreatment and FTS conditions on the formation of bulk iron carbide phases. By combining theory and experiment, it was found that the formation of θ-Fe...
\u3cp\u3e With the purpose of investigating...
Probing the product selectivity of Fischer–Tropsch catalysts is of prime scientific and industrial i...
The formation of Fe-carbide phases is relevant to the synthesis of Fischer-Tropsch synthesis catalys...
The stability and reactivity of ϵ, χ, and θ iron carbide phases in Fischer−Tropsch synthesis (FTS) c...
Iron carbides are unmistakably associated with the active phase for Fischer-Tropsch synthesis (FTS)....
The influence of different iron carbides on the activity and selectivity of iron-based Fischer–Trops...
The structure of unpromoted precipitated Fe catalysts was determined by Mössbauer emission and X-ray...
The Fe-based Fischer-Tropsch synthesis (FTS) catalyst, which converts CO and H2 into longer hydrocar...
The conversion of unpromoted, unsupported metallic iron catalysts into carbides during Fischer-Trops...
In Fe-based Fischer-Tropsch Synthesis (FTS), the Fe carbides form under the carburizing H2 : CO reac...
With the purpose of investigating the reactivity of Fe carbide as an active phase in Fischer–Tropsch...
In Fe-based Fischer-Tropsch Synthesis (FTS), the Fe carbides form under the carburizing H2 : CO reac...
\u3cp\u3e With the purpose of investigating...
Probing the product selectivity of Fischer–Tropsch catalysts is of prime scientific and industrial i...
The formation of Fe-carbide phases is relevant to the synthesis of Fischer-Tropsch synthesis catalys...
The stability and reactivity of ϵ, χ, and θ iron carbide phases in Fischer−Tropsch synthesis (FTS) c...
Iron carbides are unmistakably associated with the active phase for Fischer-Tropsch synthesis (FTS)....
The influence of different iron carbides on the activity and selectivity of iron-based Fischer–Trops...
The structure of unpromoted precipitated Fe catalysts was determined by Mössbauer emission and X-ray...
The Fe-based Fischer-Tropsch synthesis (FTS) catalyst, which converts CO and H2 into longer hydrocar...
The conversion of unpromoted, unsupported metallic iron catalysts into carbides during Fischer-Trops...
In Fe-based Fischer-Tropsch Synthesis (FTS), the Fe carbides form under the carburizing H2 : CO reac...
With the purpose of investigating the reactivity of Fe carbide as an active phase in Fischer–Tropsch...
In Fe-based Fischer-Tropsch Synthesis (FTS), the Fe carbides form under the carburizing H2 : CO reac...
\u3cp\u3e With the purpose of investigating...
Probing the product selectivity of Fischer–Tropsch catalysts is of prime scientific and industrial i...
The formation of Fe-carbide phases is relevant to the synthesis of Fischer-Tropsch synthesis catalys...
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