Chang-Il Ahn scite author profile

The amount of carbon formed and the H2/CO molar ratio for the carbon dioxide reforming (CDR) reaction with methane were investigated on Ni/Al2O3 catalyst using a laboratory-scale fixed-bed reactor and a bench-scale fluidized-bed reactor. A significant suppression of carbon deposition in the fluidized-bed reactor compared with the fixed-bed reactor can be mainly induced from different product gas flow patterns by the continuous circulation of catalysts in oxidizing and reducing regions. This approach also enhances the gasification rate of deposited carbon in an expanded catalyst bed by increasing the amount of water adsorbed. The higher H2/CO ratio above 1.0 in the fluidized-bed reactor is also attributed to the enhanced gasification rate of deposited carbon precursors. The differences in the conversions of CH4 and CO2 and the H2/CO ratios in the two reactors are responsible for the different competitive rates of the reverse water–gas shift (RWGS) reaction, the Boudouard reaction, and the gasification of carbon precursors.

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Chang-Il Ahn

Catalyst deactivation by carbon formation during CO hydrogenation to hydrocarbons on mesoporous Co3O4

Ordered mesoporous CoMO_x (M = Al or Zr) mixed oxides for Fischer–Tropsch synthesis

Fischer–Tropsch synthesis on the Al2O3-modified ordered mesoporous Co3O4 with an enhanced catalytic activity and stability

Fischer-Trospch Synthesis on Ordered Mesoporous Cobalt-Based Catalysts with Compact Multichannel Fixed-Bed Reactor Application: A Review

Effects of Carbon Formation on Catalytic Performance for CO₂ Reforming with Methane on Ni/Al₂O₃ Catalyst: Comparison of Fixed-Bed with Fluidized-Bed Reactors

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Chang-Il Ahn

Catalyst deactivation by carbon formation during CO hydrogenation to hydrocarbons on mesoporous Co3O4

Ordered mesoporous CoMOx (M = Al or Zr) mixed oxides for Fischer–Tropsch synthesis

Fischer–Tropsch synthesis on the Al2O3-modified ordered mesoporous Co3O4 with an enhanced catalytic activity and stability

Fischer-Trospch Synthesis on Ordered Mesoporous Cobalt-Based Catalysts with Compact Multichannel Fixed-Bed Reactor Application: A Review

Effects of Carbon Formation on Catalytic Performance for CO2 Reforming with Methane on Ni/Al2O3 Catalyst: Comparison of Fixed-Bed with Fluidized-Bed Reactors

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Product

Resources

About

Ordered mesoporous CoMO_x (M = Al or Zr) mixed oxides for Fischer–Tropsch synthesis

Effects of Carbon Formation on Catalytic Performance for CO₂ Reforming with Methane on Ni/Al₂O₃ Catalyst: Comparison of Fixed-Bed with Fluidized-Bed Reactors