Search results for "Fischer–Tropsch process"

showing 3 items of 3 documents

The influence of water and of alkali promotor on the carbon number distribution of fischer-tropsch products formed over iron catalysts

1987

The carbon number distribution of Fischer-Tropsch products formed over an alkalized precipitated iron catalyst has been studied as a function of the water vapor pressure of the synthesis gas. The carbon number distribution of formed hydrocarbons is characterized by a bimodal Schulz-Flory distribution of growth probabilities P1 ≈ 0.6 and P2 ≈ 0.87 attributed to unpromoted and promoted (alkalized) sites on the catalyst surface. Promoted sites are more stable with respect to oxidation (deactivation) by water than unpromoted sites. The growth probability of unpromoted sites decreases with increasing ratio P/P — Studies using Mossbauer spectroscopy have shown that iron foils treated with water c…

Chemical kineticschemistry.chemical_compoundCalcium carbonatechemistryVapor pressureGeneral Chemical EngineeringInorganic chemistryVapour pressure of waterFischer–Tropsch processAlkali metalCatalysisSyngasBerichte der Bunsengesellschaft für physikalische Chemie
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The role of nano-sized iron particles in slurry phase Fischer–Tropsch synthesis

2003

Abstract The slurry phase Fischer–Tropsch (F–T) activity of three α-Fe2O3-based materials, two unsupported nano-sized, NANOCAT (3 nm) and BASF (20–80 nm), and a supported micron-sized (32.5 μm ) UCI, are compared with respect to total hydrocarbon production from synthesis gas (H2/CO∼2/1) at 513 K. Low temperature Mossbauer spectra of the quenched slurry samples after 120 h on-line show that all three catalysts are essentially a mixture of oxide and carbide phases with magnetite (Fe3O4) being the dominant phase. TEM images of the quenched samples reveal unexpected particle characteristics. While both unsupported nano-sized materials essentially avoid expected agglomeration, the micron-sized …

Materials scienceProcess Chemistry and TechnologyInorganic chemistryOxideFischer–Tropsch processGeneral ChemistryCatalysisCarbidechemistry.chemical_compoundChemical engineeringchemistryPhase (matter)SlurryParticleMagnetiteSyngasCatalysis Communications
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Superior Fischer-Tropsch performance of uniform cobalt nanoparticles deposited into mesoporous SiC

2020

Electrochemically-derived well-crystalline mesoporous silicon carbide (pSiC) was used as a host for cobalt nanoparticles to demonstrate superior catalytic performance during the CO hydrogenation according to Fischer-Tropsch. Colloidal Co nanoparticles (9 ± 0.4 nm) were prepared independently using colloidal recipes before incorporating them into pSiC and, for comparison purposes, into commercially available silica (Davisil) as well as foam-like MCF-17 supports. The Co/pSiC catalyst demonstrated the highest (per unit mass) catalytic activity of 117 µmol.g(CO)-1.g-1(Co).s-1 at 220 °C which was larger by about one order of magnitude as compared to both silica supported cobalt catalysts. Furthe…

Mesoporous silicon carbidechemistry.chemical_elementNanoparticle010402 general chemistry01 natural sciencesCatalysisFischer-TropschCatalysischemistry.chemical_compoundCobalt nanoparticlesSilicon carbideChimieCinétique chimiquePhysical and Theoretical ChemistryComputingMilieux_MISCELLANEOUSMCF-17CO hydrogenation010405 organic chemistryFischer–Tropsch processChimie des surfaces et des interfacesPhysique des phénomènes non linéaires0104 chemical sciences[CHIM.THEO]Chemical Sciences/Theoretical and/or physical chemistrychemistryChemical engineeringSelectivityDispersion (chemistry)Mesoporous materialCatalyses hétérogène et homogèneCobaltSciences exactes et naturelles
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