4.6 Article

Tailored monolith supports for improved ultra-low temperature water-gas shift reaction

REACTION CHEMISTRY & ENGINEERING (2021)

Related references

Note: Only part of the references are listed.
Article Chemistry, Applied

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

Raquel Portela et al.

Summary: Monolithic support materials with the mechanical resistance and thermal conductivity of SiC, as well as tunable surface chemistry and textural properties, have been developed for use in catalytic membrane reactors. The skin applied onto the external wall and the infiltration of metal oxide nanoparticles into macropores allow for the immobilization of liquid phase catalysts. The resulting multimodal distribution of pore sizes can be tuned by various factors such as particle sizes, wash-coats, and calcination temperature.

CATALYSIS TODAY (2022)

Add to Collection
Article Chemistry, Physical

Ultra-low temperature water-gas shift reaction catalyzed by homogeneous Ru-complexes in a membrane reactor - membrane development and proof of concept

Morten Logemann et al.

Summary: By combining the supported ionic liquid-phase (SILP) catalyzed ultra-low temperature water-gas shift reaction (WGSR) with in situ product removal, a monolithic membrane reactor has been developed that is highly active and stable in the temperature range of 120 to 160 degrees C. The concept was proven under industrially relevant conditions using biogas feed, demonstrating for the first time the enhanced in situ removal of CO2 via facilitated transport membrane separation in combination with homogeneous SILP catalyzed WGSR.

CATALYSIS SCIENCE & TECHNOLOGY (2021)

Add to Collection
Article Chemistry, Multidisciplinary

Continuous gas-phase hydroformylation of but-1-ene in a membrane reactor by supported liquid-phase (SLP) catalysis

Morten Logemann et al.

GREEN CHEMISTRY (2020)

Add to Collection
Article Chemistry, Multidisciplinary

Elucidating the ionic liquid distribution in monolithic SILP hydroformylation catalysts by magnetic resonance imaging

Jakob Maximilian Marinkovic et al.

RSC ADVANCES (2020)

Add to Collection
Review Engineering, Chemical

Fifteen Years of Supported Ionic Liquid Phase-Catalyzed Hydroformylation: Material and Process Developments

Jakob Maximilian Marinkovic et al.

INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH (2019)

Add to Collection
Article Chemistry, Multidisciplinary

Multi-walled carbon nanotube-based composite materials as catalyst support for water-gas shift and hydroformylation reactions

Patrick Wolf et al.

RSC ADVANCES (2019)

Add to Collection
Article Chemistry, Multidisciplinary

Improving the performance of supported ionic liquid phase (SILP) catalysts for the ultra-low-temperature water-gas shift reaction using metal salt additives

Patrick Wolf et al.

GREEN CHEMISTRY (2019)

Add to Collection
Article Engineering, Chemical

CFD modeling of the influence of carrier thermal conductivity for structured catalysts in the WGS reaction

V. Palma et al.

CHEMICAL ENGINEERING SCIENCE (2018)

Add to Collection
Article Chemistry, Physical

Structured noble metal-based catalysts for the WGS process intensification

V. Palma et al.

INTERNATIONAL JOURNAL OF HYDROGEN ENERGY (2018)

Add to Collection
Article Chemistry, Physical

Dynamic equilibria in supported ionic liquid phase (SILP) catalysis: in situ IR spectroscopy identifies [Ru(CO)xCly]n species in water gas shift catalysis

Tanja Bauer et al.

CATALYSIS SCIENCE & TECHNOLOGY (2018)

Add to Collection
Article Chemistry, Physical

Novel Ni-Ce-Zr/Al2O3 Cellular Structure for the Oxidative Dehydrogenation of Ethane

Juan Pablo Bortolozzi et al.

CATALYSTS (2017)

Add to Collection
Article Engineering, Environmental

Natural silicate-TiO2 hybrids for photocatalytic oxidation of formaldehyde in gas phase

R. Portela et al.

CHEMICAL ENGINEERING JOURNAL (2017)

Add to Collection
Article Chemistry, Physical

Ultra-Low-Temperature Water-Gas Shift Catalysis using Supported Ionic Liquid Phase (SILP) Materials

Sebastian Werner et al.

CHEMCATCHEM (2010)

Add to Collection
Article Chemistry, Physical

Homogeneous ruthenium-based water-gas shift catalysts via supported ionic liquid phase (SILP) technology at low temperature and ambient pressure

Sebastian Werner et al.

PHYSICAL CHEMISTRY CHEMICAL PHYSICS (2009)

Add to Collection
Article Engineering, Chemical

Multiphase monolith reactors: Chemical reaction engineering of segmented flow in microchannels

MT Kreutzer et al.

CHEMICAL ENGINEERING SCIENCE (2005)

Add to Collection
Review Chemistry, Inorganic & Nuclear

Ionic liquids in catalysis

T Welton

COORDINATION CHEMISTRY REVIEWS (2004)

Add to Collection
Webinars Posters Questions Hubs Funding Journals Papers Connect Collections Reviewers About Us FAQs Mobile App Privacy Policy Terms of Use
© Peeref 2019-2024. All rights reserved.