660 publications in scientific journals, and thesis advisor of over 65
Ph.D. students.
Research interests include the synthesis, characterization and application of structured
catalysts (metal-organic frameworks, zeolites, monoliths, catalytic membranes) in
multiphase and multifunctional conversion processes, adsorption and diffusion in
zeolites, MOFs and their membranes, and transient kinetics.
Specific examples of heterogeneous catalysis cover Fischer-Tropsch synthesis, MTO,
selective hydrogenation and oxidation, hydroisomerization, N2O decomposition, and fine
chemicals production. Energy efficient alternatives for alkane-alkene and CO2 separation
by membranes and adsorptive heat pumps are subject of development. Light-matter
interactions are a special topic with MOFs, targeting photocatalysis and water splitting,
next to their use in electrocatalysis for energy storage.
Kapteijn coordinated recently the EU-FP7 project M4CO2 (MOF-based mixed matrix
membranes for CO2 capture in pre- and post combustion), developing energy efficient
membranes to reduce the costs of CO2 capture. The follow-up MEMBER project targets
now the demonstration in practice.
Received recently the prestigious Golden Hoogewerff medal for his Catalysis
Engineering oeuvre and the IChemE Andrew medal for the same.
[1] J. Gascon, J. R. van Ommen, J. A. Moulijn and F. Kapteijn (2015). Catalysis Science & Technology,
5, 807-817.
[2] J.A. Moulijn, M.T. Kreutzer, T.A. Nijhuis, F. Kapteijn (2011). Monolithic catalysts and reactors:
High precision with low energy consumption, in: B.C. Gates, H. Knözinger, F. Jentoft (Eds.)
Advances in Catalysis, Vol. 54, Elsevier, pp. 249-328.
[3] R. Krishna and S. T. Sie (1994). Chemical Engineering Science, 49, 4029-4065.
[4] K. V. Pangarkar (2010). Solving the heat transport issue in multiphase fixed bed reactors, PhD
Thesis, Delft University of Technology.
[5] F. Kapteijn, J.A. Moulijn (2020). Structured catalysts and reactors – Perspectives for demanding
applications, Catalysis Today, https://doi.org/10.1016/j.cattod.2020.09.026
[6] L. Oar-Arteta, T. Wezendonk, X. H. Sun, F. Kapteijn and J. Gascon (2017). Materials Chemistry
Frontiers, 1, 1709-1745.">
660 publications in scientific journals, and thesis advisor of over 65
Ph.D. students.
Research interests include the synthesis, characterization and application of structured
catalysts (metal-organic frameworks, zeolites, monoliths, catalytic membranes) in
multiphase and multifunctional conversion processes, adsorption and diffusion in
zeolites, MOFs and their membranes, and transient kinetics.
Specific examples of heterogeneous catalysis cover Fischer-Tropsch synthesis, MTO,
selective hydrogenation and oxidation, hydroisomerization, N2O decomposition, and fine
chemicals production. Energy efficient alternatives for alkane-alkene and CO2 separation
by membranes and adsorptive heat pumps are subject of development. Light-matter
interactions are a special topic with MOFs, targeting photocatalysis and water splitting,
next to their use in electrocatalysis for energy storage.
Kapteijn coordinated recently the EU-FP7 project M4CO2 (MOF-based mixed matrix
membranes for CO2 capture in pre- and post combustion), developing energy efficient
membranes to reduce the costs of CO2 capture. The follow-up MEMBER project targets
now the demonstration in practice.
Received recently the prestigious Golden Hoogewerff medal for his Catalysis
Engineering oeuvre and the IChemE Andrew medal for the same.
[1] J. Gascon, J. R. van Ommen, J. A. Moulijn and F. Kapteijn (2015). Catalysis Science & Technology,
5, 807-817.
[2] J.A. Moulijn, M.T. Kreutzer, T.A. Nijhuis, F. Kapteijn (2011). Monolithic catalysts and reactors:
High precision with low energy consumption, in: B.C. Gates, H. Knözinger, F. Jentoft (Eds.)
Advances in Catalysis, Vol. 54, Elsevier, pp. 249-328.
[3] R. Krishna and S. T. Sie (1994). Chemical Engineering Science, 49, 4029-4065.
[4] K. V. Pangarkar (2010). Solving the heat transport issue in multiphase fixed bed reactors, PhD
Thesis, Delft University of Technology.
[5] F. Kapteijn, J.A. Moulijn (2020). Structured catalysts and reactors – Perspectives for demanding
applications, Catalysis Today, https://doi.org/10.1016/j.cattod.2020.09.026
[6] L. Oar-Arteta, T. Wezendonk, X. H. Sun, F. Kapteijn and J. Gascon (2017). Materials Chemistry
Frontiers, 1, 1709-1745." />
660 publications in scientific journals, and thesis advisor of over 65
Ph.D. students.
Research interests include the synthesis, characterization and application of structured
catalysts (metal-organic frameworks, zeolites, monoliths, catalytic membranes) in
multiphase and multifunctional conversion processes, adsorption and diffusion in
zeolites, MOFs and their membranes, and transient kinetics.
Specific examples of heterogeneous catalysis cover Fischer-Tropsch synthesis, MTO,
selective hydrogenation and oxidation, hydroisomerization, N2O decomposition, and fine
chemicals production. Energy efficient alternatives for alkane-alkene and CO2 separation
by membranes and adsorptive heat pumps are subject of development. Light-matter
interactions are a special topic with MOFs, targeting photocatalysis and water splitting,
next to their use in electrocatalysis for energy storage.
Kapteijn coordinated recently the EU-FP7 project M4CO2 (MOF-based mixed matrix
membranes for CO2 capture in pre- and post combustion), developing energy efficient
membranes to reduce the costs of CO2 capture. The follow-up MEMBER project targets
now the demonstration in practice.
Received recently the prestigious Golden Hoogewerff medal for his Catalysis
Engineering oeuvre and the IChemE Andrew medal for the same.
[1] J. Gascon, J. R. van Ommen, J. A. Moulijn and F. Kapteijn (2015). Catalysis Science & Technology,
5, 807-817.
[2] J.A. Moulijn, M.T. Kreutzer, T.A. Nijhuis, F. Kapteijn (2011). Monolithic catalysts and reactors:
High precision with low energy consumption, in: B.C. Gates, H. Knözinger, F. Jentoft (Eds.)
Advances in Catalysis, Vol. 54, Elsevier, pp. 249-328.
[3] R. Krishna and S. T. Sie (1994). Chemical Engineering Science, 49, 4029-4065.
[4] K. V. Pangarkar (2010). Solving the heat transport issue in multiphase fixed bed reactors, PhD
Thesis, Delft University of Technology.
[5] F. Kapteijn, J.A. Moulijn (2020). Structured catalysts and reactors – Perspectives for demanding
applications, Catalysis Today, https://doi.org/10.1016/j.cattod.2020.09.026
[6] L. Oar-Arteta, T. Wezendonk, X. H. Sun, F. Kapteijn and J. Gascon (2017). Materials Chemistry
Frontiers, 1, 1709-1745." />
Reflections on Structured Catalysts and Reactors
Freek Kapteijn, Catalysis Engineering-ChemE, Delft University of TechnologyCambridge Fluids Network - fluids-related seminars21 June 2021 11:00amhttps://teams.microsoft.com/l/meetup-join/19:b7df45856d814c06bdec7db948bbaa39@thread.tacv2/1623258821761?context=%7B%22Tid%22:%2249a50445-bdfa-4b79-ade3-547b4f3986e9%22,%22Oid%22:%22026c67ed-9f3a-40b8-9234-48eb6576dfe8%22%7DPlease join this talk in "Microsoft Teams":https://teams.microsoft.com/l/meetup-join/19:b7df45856d814c06bdec7db948bbaa39@thread.tacv2/1623258821761?context=%7B%22Tid%22:%2249a50445-bdfa-4b79-ade3-547b4f3986e9%22,%22Oid%22:%22026c67ed-9f3a-40b8-9234-48eb6576dfe8%22%7D
After their successful introduction in emission control in the form of monoliths, structured
catalysts and reactors have been explored the last decades for application in catalytic multiphase
processes [1,2]. They facilitate following the optimal reactor selection approach of Krishna and
Sie ('to mix or not to mix') [3], where conflicting design requirements can still be realized in a
structured reactor.
An interesting approach is to analyse the relative resistances of the various steps in de overall
reaction acting in a multiphase catalytic reactor. Use of structured catalysts/reactor internals can
eliminate or alleviate major hurdles, changing their interplay in the process [4,5]. The question
then arises what resistance distribution is desired and what are essential guiding rules of thumb
to determine the focus for the optimization of the structured catalyst-reactor internal.
The quest for process intensification has triggered new directions of improving catalysts for
classical reactions. Using metal-organic frameworks as a catalyst precursor has been successful
in the preparation of extremely active low- and high-temperature Fischer-Tropsch catalysts [6].
This changes the relative resistances in that process and new challenges arise to accommodate
these systems, calling for structured reactors. New technologies, like 3D printing offer new
opportunities to meet these requirements.
*Bio*
Freek Kapteijn (1952, Amsterdam) graduated in 1974 at the
university of Amsterdam in Chemistry and Mathematics. His
Ph.D. on the metathesis of alkenes was received at the same
university. As postdoc he focused on Coal Science and
Heterogeneous Catalysis. In 1987 he received a tenured
position at the University of Amsterdam.
In 1992 he moved to Delft University of Technology, where he
was appointed ‘Anthonie van Leeuwenhoek’ professor in 1999.
He has assumed leadership of the Catalysis Engineering
section in 2008, and became emeritus in 2018.
Kapteijn had visiting appointments in Nancy, France
(Villermaux, ENSIC) and Zürich, Switzerland (Prins, ETH), and as guest professor at
Zhejiang Normal University, China since 2008.
He is co-author of >660 publications in scientific journals, and thesis advisor of over 65
Ph.D. students.
Research interests include the synthesis, characterization and application of structured
catalysts (metal-organic frameworks, zeolites, monoliths, catalytic membranes) in
multiphase and multifunctional conversion processes, adsorption and diffusion in
zeolites, MOFs and their membranes, and transient kinetics.
Specific examples of heterogeneous catalysis cover Fischer-Tropsch synthesis, MTO,
selective hydrogenation and oxidation, hydroisomerization, N2O decomposition, and fine
chemicals production. Energy efficient alternatives for alkane-alkene and CO2 separation
by membranes and adsorptive heat pumps are subject of development. Light-matter
interactions are a special topic with MOFs, targeting photocatalysis and water splitting,
next to their use in electrocatalysis for energy storage.
Kapteijn coordinated recently the EU-FP7 project M4CO2 (MOF-based mixed matrix
membranes for CO2 capture in pre- and post combustion), developing energy efficient
membranes to reduce the costs of CO2 capture. The follow-up MEMBER project targets
now the demonstration in practice.
Received recently the prestigious Golden Hoogewerff medal for his Catalysis
Engineering oeuvre and the IChemE Andrew medal for the same.
[1] J. Gascon, J. R. van Ommen, J. A. Moulijn and F. Kapteijn (2015). Catalysis Science & Technology,
5, 807-817.
[2] J.A. Moulijn, M.T. Kreutzer, T.A. Nijhuis, F. Kapteijn (2011). Monolithic catalysts and reactors:
High precision with low energy consumption, in: B.C. Gates, H. Knözinger, F. Jentoft (Eds.)
Advances in Catalysis, Vol. 54, Elsevier, pp. 249-328.
[3] R. Krishna and S. T. Sie (1994). Chemical Engineering Science, 49, 4029-4065.
[4] K. V. Pangarkar (2010). Solving the heat transport issue in multiphase fixed bed reactors, PhD
Thesis, Delft University of Technology.
[5] F. Kapteijn, J.A. Moulijn (2020). Structured catalysts and reactors – Perspectives for demanding
applications, Catalysis Today, https://doi.org/10.1016/j.cattod.2020.09.026
[6] L. Oar-Arteta, T. Wezendonk, X. H. Sun, F. Kapteijn and J. Gascon (2017). Materials Chemistry
Frontiers, 1, 1709-1745.