| Tu_S5 |
Tuesday, June 30th |
8:30-10:40 |
Chairmen: Zinfer Ismagilov / Freek Kapteijn |
| Session 5 |
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Reference |
Name |
First Name |
Topic |
Title |
| 8:30-9:10 |
S5-C |
DE GROOT |
Arend |
1.4 CMRs applied to energy production |
Membrane reactors for the chemical industry: Understanding Benefits & Barriers, Priorities |
| 9:10-9:30 |
S5-O1 |
DEMANGE |
David |
1.4 CMRs applied to energy production |
Counter-current isotope swamping in a membrane reactor: the PERMCAT process and its applications in fusion technology |
| 9:30-9:50 |
S5-O2 |
BARBIERI |
Giuseppe |
1.4 CMRs applied to energy production |
CO inhibition effect on Pd-based membrane reactors performance for water gas shift reaction |
| 9:50-10:10 |
S5-O3 |
DELBOS |
Cédric |
1.4 CMRs applied to energy production |
Performances of tubular La0.8Sr0.2Fe0.7Ga0.3O3-d mixed ionic and electronic conductor membrane reactor for methane conversion to syngas at high pressure |
| 10:10-10:40 |
S5-P1 |
CHIAPPETTA |
Giovanni |
1.4 CMRs applied to energy production |
Membrane Reactors on small scale for the methane steam reforming reaction: assessment on the high pressure importance |
| S5-P2 |
COMITE |
Antonio |
1.4 CMRs applied to energy production |
Pd membranes supported on porous stainless steel with an inter-metallic Al2O3 diffusion barrier |
| S5-P3 |
FEDOTOV |
Alexey |
1.4 CMRs applied to energy production |
Dry methane reforming on porous ceramic catalytic membranes modified by La-Ce and Pd-Mn catalysts |
| S5-P4 |
GOLDBACH |
Andreas |
1.4 CMRs applied to energy production |
Evaluation of water-gas shift Pd membrane reactors with Pt/Ce0.6Zr0.4O2 catalyst for CO2 capture |
| S5-P5 |
HARA |
Shigeki |
1.4 CMRs applied to energy production |
Ethanol steam reforming in a palladium membrane reactor without using sweep gas |
| S5-P6 |
MENDES |
Diogo |
1.4 CMRs applied to energy production |
A Pd-Ag "Finger-like" Configuration Membrane Reactor for the Low-Temperature Water-Gas Shift Reaction |
| S5-P7 |
PARVULESCU |
Viorica |
1.4 CMRs applied to energy production |
Direct oxidation of hydrocarbons in electrocatalytic membrane reactor |
| S5-P8 |
ROUESSAC |
Vincent |
1.4 CMRs applied to energy production |
PECVD silicon carbonitride membranes permselective to H2 |
| S5-P9 |
SANCHEZ |
Josemaria |
1.4 CMRs applied to energy production |
Preliminary Studies of Water Gas Shift catalysts and a Pd-based membrane for H2 and CO2 production & separation in a Catalytic Membrane Reactor |
| Tu_S6 |
Tuesday, June 30th |
11:00-13:10 |
Chairmen: Rune Bredesen / Yi Hua Ma |
| Session 6 |
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Reference |
Name |
First Name |
Topic |
Title |
| 11:00-11:30 |
S6-K |
WANG |
Haihui |
1.4 CMRs applied to energy production |
Novel tantalum doped perovskite BaCo0.7Fe0.2Ta0.1O3-d for oxygen separation and POM |
| 11:30-11:50 |
S6-O1 |
GOLDBACH |
Andreas |
1.4 CMRs applied to energy production |
Investigation of H2 permeation rates in Pd membrane steam reformers |
| 11:50-12:10 |
S6-O2 |
LOMBARDO |
Eduardo A. |
1.4 CMRs applied to energy production |
Consecutive methane oxidation and CO2 reforming conducted in a Pd-Ag alloy membrane reactor to produce ultrapure H2 |
| 12:10-12:30 |
S6-O3 |
NISHII |
Takumi |
1.4 CMRs applied to energy production |
Reforming Performance of Hydrogen Production Module Based on Membrane On Catalyst |
| 12:30-13:10 |
S6-P1 |
TORRES RODRIGUEZ |
Miguel |
1.4 CMRs applied to energy production |
Comparative study a fixed-bed reactor and membrane reactor for the wet reforming ethanol |
| S6-P2 |
VAN DELFT |
Yvonne |
1.4 CMRs applied to energy production |
Towards the Application of Palladium Membrane Reactors in Hydrogen Production |
| S6-P3 |
YEUNG |
King Lun |
1.4 CMRs applied to energy production |
Cellulose supported HZSM-5 membrane for PEMFC application |
| S6-P4 |
YEUNG |
King Lun |
1.4 CMRs applied to energy production |
H2 production from partial oxidation of methane in a dual membrane reactor |
| S6-P5 |
BANDYOPADHYAY |
Sibdas |
1.2 CMRs applied to environmental issues |
Ceramic membrane contactors for CO2 capture |
| S6-P6 |
BANDYOPADHYAY |
Sibdas |
1.2 CMRs applied to environmental issues |
Ceramic Membrane Bioreactor for grey water treatment |
| S6-P7 |
MOZIA |
Sylwia |
1.2 CMRs applied to environmental issues |
Immobilized photocatalytic reactor - membrane distillation system for removal of azo dyes from water |
| S6-P8 |
MOZIA |
Sylwia |
1.2 CMRs applied to environmental issues |
Integration of photocatalysis with membrane processes for purification of water contaminated with organic dyes |
| S6-P9 |
PARVULESCU |
Viorica |
1.2 CMRs applied to environmental issues |
Organic functionalized ZSM-5 zeolite membranes for CO2 separation |
| S6-P10 |
YEUNG |
King Lun |
1.2 CMRs applied to environmental issues |
Experiment and model of diclofenac degradation in an advanced ozone membrane reactor |
| S6-P11 |
GIROIR-FENDLER |
Anne |
1.2 CMRs applied to environmental issues |
Comparing monolithic and membrane reactors in catalytic oxida-tion of propene and toluene in excess of oxygen |
| S6-P12 |
MAISTERRENA |
Bernard |
1.3 CMRs applied to biological processes |
Biomimetic enzymatic membranes for specific active transport processes: the shunt concept |
| Tu_S7 |
Tuesday, June 30th |
14:30-16:45 |
Chairmen: Nolven Guilhaume / Eduardo Lombardo |
| Session 7 |
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Reference |
Name |
First Name |
Topic |
Title |
| 14:30-14:50 |
S7-O1 |
BREDESEN |
Rune |
1.4 CMRs applied to energy production |
Development of thin Pd-23%Ag/Stainless Steel composite membranes for application in Water Gas Shift membrane reactors |
| 14:50-15:10 |
S7-O2 |
PIETERSE |
Johannis |
1.4 CMRs applied to energy production |
Steam Reforming in Membrane Reactors using Nickel Catalysts |
| 15:10-15:30 |
S7-O3 |
PINACCI |
Pietro |
1.4 CMRs applied to energy production |
Evaluation of the water gas shift reaction in a palladium membrane reactor |
| 15:30-15:50 |
S7-O4 |
MEZENTSEVA |
Natalia |
1.4 CMRs applied to energy production |
Design of assymetric multilayer membranes based on mixed ionic-electronic conducting composites |
| 15:50-16:45 |
S7-P1 |
ANCHAROVA |
Uliana |
2. Membranes for CMRs |
Effects of nanostructuring in oxygen-permeable membrane materials on the base of mixed conducting perovskites ABO2.5x |
| S7-P2 |
BRICEÑO |
Kelly |
2. Membranes for CMRs |
Ceramic-supported membranes for hydrogen separation |
| S7-P3 |
CARO |
Juergen |
2. Membranes for CMRs |
Basic aspects of catalytic membrane reactors |
| S7-P4 |
DENG |
Zhiyong |
2. Membranes for CMRs |
Preparation of MFI-alumina membrane by pore-plugging |
| S7-P5 |
FERNÁNDEZ |
Ekain |
2. Membranes for CMRs |
Preparation and characterization of palladium-based membranes for hydrogen production |
| S7-P6 |
HARA |
Shigeki |
2. Membranes for CMRs |
Pressure-dependent hydrogen permeability evaluated using a thick |
| S7-P7 |
ISMAGILOV |
Zinfer |
2. Membranes for CMRs |
Study of Nb-doped SrCo0.8Fe0.2O3-d perovskites as promising materials for oxygen-conducting membranes |
| S7-P9 |
KINGSBURY |
Ben |
2. Membranes for CMRs |
A morphological study of asymmetric alumina hollow fibre membranes: A perspective on multifunctional catalytic membrane reactors |
| S7-P10 |
GUO |
Yanglong |
2. Membranes for CMRs |
Preparation and Characterization of well-intergrowth ZSM-5 zeolite membrane |
| S7-P11 |
RICHTER |
Hannes |
2. Membranes for CMRs |
Hydrogen peroxide direct synthesis in a catalytic membrane contactor - membrane preparation |
| S7-P12 |
RODULFO-BAECHLER |
Serbia |
2. Membranes for CMRs |
Oxygen permeation studies on LSCF hollow fibre membranes |
| S7-P13 |
SAVINSKAYA |
Olga |
2. Membranes for CMRs |
Structural investigation and oxygen transport through SrFe1-xMoxO3-z nanostructured membrane |
| S7-P14 |
INAYAT |
Amer |
2. Membranes for CMRs |
Defect-free BEA and MFI membranes with high Al content and their potential use in membrane reactors |
| S7-P15 |
SOUKUP |
Karel |
2. Membranes for CMRs |
Nanofiber membranes - evaluation of transport properties |
| S7-P16 |
VAN DELFT |
Yvonne |
2. Membranes for CMRs |
Stable HybSi® nanosieve membranes for dehydration of biofuels |
| S7-P17 |
WOHLRAB |
Sebastian |
2. Membranes for CMRs |
Oxygen transport characteristics of dense membranes of the type La2Ni0.9M0.1O4-x, with M = Ni, Co and Cu |
| Tu_S8 |
Tuesday, June 30th |
17:00-18:30 |
Chairmen: Marc Pera-Titus / King Lun Yeung
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| Session 8 |
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Reference |
Name |
First Name |
Topic |
Title |
| 17:00-17:30 |
S8-K |
LI |
Kang |
1.1 CMRs applied to chemical synthesis |
A Multifunctional Hollow Fibre Membrane Reactor for Catalytic Dehydrogenation of Propane |
| 17:30-17:50 |
S8-O1 |
EBERT |
Katrin |
2. Membranes for CMRs |
Nanofibres with high catalytical activity tested in the hydrogenation of methyl-cis-9-octadecenoate |
| 17:50-18:10 |
S8-O2 |
LAHITTE |
Jean-Francois |
1.1 CMRs applied to chemical synthesis |
Preparation of catalytic hollow fiber membranes containing metal nanoparticles by two surface modification techniques |
| 18:10-18:30 |
S8-O3 |
JIANG |
Heqing |
1.4 CMRs applied to energy production |
Improved nitrous oxide decomposition and water splitting by in-situ oxygen removal in perovskite catalytic membrane reactor |