Optimization of Catalysts for Fischer‐Tropsch Synthesis by Introduction of Transport Pores: Fid-Bau Portal

Fachinformationsdienst BAUdigital

A platform for research: civil engineering, architecture and urbanism

Optimization of Catalysts for Fischer‐Tropsch Synthesis by Introduction of Transport Pores

Becker, Henning / Güttel, Robert / Turek, Thomas

Diffusional restrictions in the porous network of Fischer‐Tropsch catalysts strongly affect activity and product selectivity. Especially small pores hamper the diffusion of reactants. In order to overcome the diffusion restrictions, the introduction of transport pores into the catalyst and the resulting effect on reaction rate and selectivities were studied. It was shown that transport pores allow for an increase in diffusion length, maintaining high reaction rate and C₅₊ selectivity. Overall, the productivity can be increased through optimization of the transport pore fraction.

Access

Check availability in my library

Order at Subito €

Page navigation

Document information

Export, share and cite

Optimization of Catalysts for Fischer‐Tropsch Synthesis by Introduction of Transport Pores

Becker, Henning / Güttel, Robert / Turek, Thomas

Diffusional restrictions in the porous network of Fischer‐Tropsch catalysts strongly affect activity and product selectivity. Especially small pores hamper the diffusion of reactants. In order to overcome the diffusion restrictions, the introduction of transport pores into the catalyst and the resulting effect on reaction rate and selectivities were studied. It was shown that transport pores allow for an increase in diffusion length, maintaining high reaction rate and C₅₊ selectivity. Overall, the productivity can be increased through optimization of the transport pore fraction.

Optimization of Catalysts for Fischer‐Tropsch Synthesis by Introduction of Transport Pores

Becker, Henning / Güttel, Robert / Turek, Thomas

Diffusional restrictions in the porous network of Fischer‐Tropsch catalysts strongly affect activity and product selectivity. Especially small pores hamper the diffusion of reactants. In order to overcome the diffusion restrictions, the introduction of transport pores into the catalyst and the resulting effect on reaction rate and selectivities were studied. It was shown that transport pores allow for an increase in diffusion length, maintaining high reaction rate and C₅₊ selectivity. Overall, the productivity can be increased through optimization of the transport pore fraction.

Access

Check availability in my library

Order at Subito €

Page navigation

Document information

Export, share and cite

Document information

Title:

Optimization of Catalysts for Fischer‐Tropsch Synthesis by Introduction of Transport Pores

Contributors:

Becker, Henning (author) / Güttel, Robert (author) / Turek, Thomas (author)

Published in:

Chemie Ingenieur Technik ; 86 ; 544-549

Publication date:

2014-04-01

Size:

6 pages

ISSN:

0009-286X , 1522-2640

DOI:

https://doi.org/10.1002/cite.201300142

Type of media:

Article (Journal)

Type of material:

Electronic Resource

Language:

English

Keywords:

Bimodal pore system , Simulation , Fischer‐Tropsch synthesis

Similar titles

3D Modeling of a Catalyst Layer with Transport Pores for Fischer‐Tropsch Synthesis

Bufe, Alexander / Klee, Matthias / Wehinger, Gregor et al. | Wiley | 2017

Aluminosilicate-supported cobalt catalysts in the Fischer-Tropsch synthesis

Lapidus, A. L. / Pavlova, V. A. / Chin, N. K. et al. | Springer Verlag | 2009

Iron‐Based Fischer‐Tropsch Catalysts for Higher Alcohol Synthesis

Schaller, Max / Reichelt, Erik / Jahn, Matthias | Wiley | 2018

Iron‐Based Fischer‐Tropsch Catalysts for Higher Alcohol Synthesis

Schaller, Max / Reichelt, Erik / Jahn, Matthias | Wiley | 2019

Fischer–Tropsch Synthesis over Bifunctional Catalysts Based on HBeta Zeolite

Papeta, O. P. / Sulima, S. I. / Bakun, V. G. et al. | Springer Verlag | 2023