Monolithic SiC supports with tailored hierarchical porosity for molecularly selective membranes and supported liquid-phase catalysis

Raquel Portela; Jakob Maximilian Marinkovic; Morten Logemann; Markus Schörner; Nanette Zahrtman; Esra Eray; Marco Haumann; Eduardo J. García-Suárez; Matthias Wessling; Pedro Ávila; Anders Riisager; Rasmus Fehrmann

doi:10.1016/j.cattod.2020.06.045

Monolithic SiC supports with tailored hierarchical porosity for molecularly selective membranes and supported liquid-phase catalysis

Raquel Portela^*, Jakob Maximilian Marinkovic, Morten Logemann, Markus Schörner, Nanette Zahrtman, Esra Eray, Marco Haumann, Eduardo J. García-Suárez, Matthias Wessling, Pedro Ávila, Anders Riisager, Rasmus Fehrmann

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › Research › peer-review

7 Citations (Scopus)

Abstract

Monolithic support materials with the mechanical resistance and thermal conductivity of SiC as well as tunable surface chemistry and textural properties were developed for their use in catalytic membrane reactors. After heat treatment, the extruded SiC monoliths have a monomodal distribution of macropores of a few μm in diameter depending on the particle size of the starting material. A macroporous, defect-free, smoother skin was applied onto the external wall using a solution of sub-micrometer SiC particles. These monoliths with skin could be coated successfully with molecularly selective membranes, and thus have application in membrane reactor processes. Finally, metal oxide nanoparticles were infiltrated into the macropores to modify the surface texture and chemistry, allowing the immobilization of liquid phase catalysts. The resulting multimodal distribution of pore sizes could be tuned by the choice of SiC and oxide particle sizes, number of wash-coats and calcination temperature. Mesopores created between nanoparticles had diameters of roughly 40 % of those of the nanoparticles. Small macropores, between 10−1000 nm, were also created, with bigger size and volume at higher calcination temperatures due to the metal oxide particles contraction. The developed materials were validated as support for PDMS membranes and for continuous gas-phase hydroformylation of 1-butene using Rh-diphosphite catalysts.

Original language	English
Journal	Catalysis Today
ISSN	0920-5861
DOIs	https://doi.org/10.1016/j.cattod.2020.06.045
Publication status	Accepted/In press - 2020
Externally published	Yes

Bibliographical note

Funding Information:
The authors gratefully acknowledge financial support from the European Commissionwithin the Horizon2020-SPIRE project ROMEO (Grant Agreement Number 680395). Furthermore, the authors would like to thank Dr. Andreas B?smann and M. Sc. Patrick Wolf (Universit?t Erlangen-N?rnberg) for the XRF measurements, as well as Markus Wist (RWTH Aachen University) for his work in the membrane fabrication.

Funding Information:
The authors gratefully acknowledge financial support from the European Commission within the Horizon2020-SPIRE project ROMEO (Grant Agreement Number 680395) . Furthermore, the authors would like to thank Dr. Andreas Bösmann and M. Sc. Patrick Wolf (Universität Erlangen-Nürnberg) for the XRF measurements, as well as Markus Wist (RWTH Aachen University) for his work in the membrane fabrication.

Publisher Copyright:
© 2020 Elsevier B.V.

Keywords

Catalysis
Hydroformylation
Molecularly selective membrane
Monolith
Porosity
Silicon carbide

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10.1016/j.cattod.2020.06.045

Cite this

Portela, R., Marinkovic, J. M., Logemann, M., Schörner, M., Zahrtman, N., Eray, E., Haumann, M., García-Suárez, E. J., Wessling, M., Ávila, P., Riisager, A., & Fehrmann, R. (Accepted/In press). Monolithic SiC supports with tailored hierarchical porosity for molecularly selective membranes and supported liquid-phase catalysis. Catalysis Today. https://doi.org/10.1016/j.cattod.2020.06.045

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title = "Monolithic SiC supports with tailored hierarchical porosity for molecularly selective membranes and supported liquid-phase catalysis",

abstract = "Monolithic support materials with the mechanical resistance and thermal conductivity of SiC as well as tunable surface chemistry and textural properties were developed for their use in catalytic membrane reactors. After heat treatment, the extruded SiC monoliths have a monomodal distribution of macropores of a few μm in diameter depending on the particle size of the starting material. A macroporous, defect-free, smoother skin was applied onto the external wall using a solution of sub-micrometer SiC particles. These monoliths with skin could be coated successfully with molecularly selective membranes, and thus have application in membrane reactor processes. Finally, metal oxide nanoparticles were infiltrated into the macropores to modify the surface texture and chemistry, allowing the immobilization of liquid phase catalysts. The resulting multimodal distribution of pore sizes could be tuned by the choice of SiC and oxide particle sizes, number of wash-coats and calcination temperature. Mesopores created between nanoparticles had diameters of roughly 40 % of those of the nanoparticles. Small macropores, between 10−1000 nm, were also created, with bigger size and volume at higher calcination temperatures due to the metal oxide particles contraction. The developed materials were validated as support for PDMS membranes and for continuous gas-phase hydroformylation of 1-butene using Rh-diphosphite catalysts.",

keywords = "Catalysis, Hydroformylation, Molecularly selective membrane, Monolith, Porosity, Silicon carbide",

author = "Raquel Portela and Marinkovic, {Jakob Maximilian} and Morten Logemann and Markus Sch{\"o}rner and Nanette Zahrtman and Esra Eray and Marco Haumann and Garc{\'i}a-Su{\'a}rez, {Eduardo J.} and Matthias Wessling and Pedro {\'A}vila and Anders Riisager and Rasmus Fehrmann",

note = "Funding Information: The authors gratefully acknowledge financial support from the European Commissionwithin the Horizon2020-SPIRE project ROMEO (Grant Agreement Number 680395). Furthermore, the authors would like to thank Dr. Andreas B?smann and M. Sc. Patrick Wolf (Universit?t Erlangen-N?rnberg) for the XRF measurements, as well as Markus Wist (RWTH Aachen University) for his work in the membrane fabrication. Funding Information: The authors gratefully acknowledge financial support from the European Commission within the Horizon2020-SPIRE project ROMEO (Grant Agreement Number 680395) . Furthermore, the authors would like to thank Dr. Andreas B{\"o}smann and M. Sc. Patrick Wolf (Universit{\"a}t Erlangen-N{\"u}rnberg) for the XRF measurements, as well as Markus Wist (RWTH Aachen University) for his work in the membrane fabrication. Publisher Copyright: {\textcopyright} 2020 Elsevier B.V.",

year = "2020",

doi = "10.1016/j.cattod.2020.06.045",

language = "English",

journal = "Catalysis Today",

issn = "0920-5861",

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T1 - Monolithic SiC supports with tailored hierarchical porosity for molecularly selective membranes and supported liquid-phase catalysis

AU - Portela, Raquel

AU - Marinkovic, Jakob Maximilian

AU - Logemann, Morten

AU - Schörner, Markus

AU - Zahrtman, Nanette

AU - Eray, Esra

AU - Haumann, Marco

AU - García-Suárez, Eduardo J.

AU - Wessling, Matthias

AU - Ávila, Pedro

AU - Riisager, Anders

AU - Fehrmann, Rasmus

N1 - Funding Information: The authors gratefully acknowledge financial support from the European Commissionwithin the Horizon2020-SPIRE project ROMEO (Grant Agreement Number 680395). Furthermore, the authors would like to thank Dr. Andreas B?smann and M. Sc. Patrick Wolf (Universit?t Erlangen-N?rnberg) for the XRF measurements, as well as Markus Wist (RWTH Aachen University) for his work in the membrane fabrication. Funding Information: The authors gratefully acknowledge financial support from the European Commission within the Horizon2020-SPIRE project ROMEO (Grant Agreement Number 680395) . Furthermore, the authors would like to thank Dr. Andreas Bösmann and M. Sc. Patrick Wolf (Universität Erlangen-Nürnberg) for the XRF measurements, as well as Markus Wist (RWTH Aachen University) for his work in the membrane fabrication. Publisher Copyright: © 2020 Elsevier B.V.

PY - 2020

Y1 - 2020

N2 - Monolithic support materials with the mechanical resistance and thermal conductivity of SiC as well as tunable surface chemistry and textural properties were developed for their use in catalytic membrane reactors. After heat treatment, the extruded SiC monoliths have a monomodal distribution of macropores of a few μm in diameter depending on the particle size of the starting material. A macroporous, defect-free, smoother skin was applied onto the external wall using a solution of sub-micrometer SiC particles. These monoliths with skin could be coated successfully with molecularly selective membranes, and thus have application in membrane reactor processes. Finally, metal oxide nanoparticles were infiltrated into the macropores to modify the surface texture and chemistry, allowing the immobilization of liquid phase catalysts. The resulting multimodal distribution of pore sizes could be tuned by the choice of SiC and oxide particle sizes, number of wash-coats and calcination temperature. Mesopores created between nanoparticles had diameters of roughly 40 % of those of the nanoparticles. Small macropores, between 10−1000 nm, were also created, with bigger size and volume at higher calcination temperatures due to the metal oxide particles contraction. The developed materials were validated as support for PDMS membranes and for continuous gas-phase hydroformylation of 1-butene using Rh-diphosphite catalysts.

AB - Monolithic support materials with the mechanical resistance and thermal conductivity of SiC as well as tunable surface chemistry and textural properties were developed for their use in catalytic membrane reactors. After heat treatment, the extruded SiC monoliths have a monomodal distribution of macropores of a few μm in diameter depending on the particle size of the starting material. A macroporous, defect-free, smoother skin was applied onto the external wall using a solution of sub-micrometer SiC particles. These monoliths with skin could be coated successfully with molecularly selective membranes, and thus have application in membrane reactor processes. Finally, metal oxide nanoparticles were infiltrated into the macropores to modify the surface texture and chemistry, allowing the immobilization of liquid phase catalysts. The resulting multimodal distribution of pore sizes could be tuned by the choice of SiC and oxide particle sizes, number of wash-coats and calcination temperature. Mesopores created between nanoparticles had diameters of roughly 40 % of those of the nanoparticles. Small macropores, between 10−1000 nm, were also created, with bigger size and volume at higher calcination temperatures due to the metal oxide particles contraction. The developed materials were validated as support for PDMS membranes and for continuous gas-phase hydroformylation of 1-butene using Rh-diphosphite catalysts.

KW - Catalysis

KW - Hydroformylation

KW - Molecularly selective membrane

KW - Monolith

KW - Porosity

KW - Silicon carbide

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U2 - 10.1016/j.cattod.2020.06.045

DO - 10.1016/j.cattod.2020.06.045

M3 - Journal article

AN - SCOPUS:85087220815

SN - 0920-5861

JO - Catalysis Today

JF - Catalysis Today

ER -

Monolithic SiC supports with tailored hierarchical porosity for molecularly selective membranes and supported liquid-phase catalysis

Abstract

Bibliographical note

Keywords

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Development of Silicon Carbide Membranes for Efficient Treatment of Wastewater Streams: From Material to Application

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