Adsorption et réduction du bleu de méthylène en régime chimique ,
, 2. Ag-NPs doping of OCPUF@PDA: preparation of OCPUF@PDA@Ag
Silver NPs doping of the soft structured OCPUF@PDA redox mediator: catalytic activity of OCPUF@PDA@Ag ,
,
,
, Matériaux hybrides : mousses de polyuréthane fonctionnalisées par un matériau carboné, vol.3
73 3.1 Characterization of the CM supported on the open cell foam, Corrosion Science, vol.96, pp.67-73 ,
Adsorption of methylene blue by a high-efficiency adsorbent (polydopamine microspheres): Kinetics, isotherm, thermodynamics and mechanism analysis, Chemical Engineering Journal, vol.259, pp.53-61, 2015. ,
, Bioresource Technology, vol.101, issue.9, pp.3040-3046, 2010.
,
« Polyurethane foams synthesized from cellulose-based wastes: Kinetics studies of dye adsorption, Références bibliographiques, vol.85, p.149, 2016. ,
, The removal of colour from textile wastewater using whole bacterial cells: a review, vol.58, p.179
, 196, sept, 2003.
« Adsorption of methylene blue on low-cost adsorbents: A review, Journal of Hazardous Materials, vol.177, p.70, 2010. ,
,
, CoMg/SBA-15 for the degradation of dye Rhodamine B in aqueous solution, Applied Catalysis B: Environmental, vol.134, issue.135, pp.7-18, 2013.
, Graphene Oxide Modified Ag
, O Nanocomposites with Enhanced Photocatalytic Activity under Visible-Light Irradiation
, Graphene Oxide Modified Ag 2 O Nanocomposites, vol.2013, p.6119, 2013.
« Improved immobilization of biomolecules to quinone-rich polydopamine for efficient surface functionalization, Colloids and Surfaces B: Biointerfaces, vol.106, pp.66-73, 2013. ,
Adsorption of methylene blue by a high-efficiency adsorbent (polydopamine microspheres): Kinetics, isotherm, thermodynamics and mechanism analysis, Chemical Engineering Journal, vol.259, pp.53-61, 2015. ,
« Removal of hazardous organics from water using metalorganic frameworks (MOFs): Plausible mechanisms for selective adsorptions, Journal of Hazardous Materials, vol.283, pp.329-339, 2015. ,
, « Magnetically recoverable core-shell nanocomposites ?-Fe2O3@SiO2@TiO2-Ag with enhanced photocatalytic activity and
,
Versatile Materials and Sustainable Problem Solvers for Today's Challenges », Angewandte Chemie International Edition, vol.52, pp.9422-9441, 2013. ,
« Pressure drop modeling on SOLID foam: State-of-the art correlation, Chemical Engineering Journal, vol.144, issue.2, p.299 ,
« Towards a more realistic modeling of solid foam: Use of the pentagonal dodecahedron geometry, Chemical Engineering Science, vol.64, p.5131, 2009. ,
« Porous plastic foam filtration media: penetration characteristics and applications in particle size-selective sampling, Journal of Aerosol Science, vol.24, issue.7, pp.929933-931944, 1993. ,
« Properties of ceramic foam catalyst supports: mass and heat transfer, Applied Catalysis A: General, vol.250, issue.2, p.319, 2003. ,
,
, High performance structured platelet milli-reactor filled with supported cobalt open cell SiC foam catalyst for the Fischer-Tropsch synthesis, Chemical Engineering Journal, vol.222, p.265, 2013.
,
Hydrodynamics and mass transfer in a tubular reactor containing foam packings for intensification of G-L-S catalytic reactions in co-current up-flow configuration, Chemical Engineering Research and Design, vol.109, pp.686-697, 2016. ,
URL : https://hal.archives-ouvertes.fr/hal-01925607
« Rotating reactors -A review, Chemical Engineering Research and Design, vol.91, issue.10, 19231940-10. ,
, Review on methods to deposit catalysts on structured surfaces, vol.315, pp.1-17, 2006.
URL : https://hal.archives-ouvertes.fr/hal-00115981
« The mechanical behavior of foamed aluminum, Journal of materials science, vol.34, issue.2, pp.291-299, 1999. ,
« Residence time distribution, axial liquid dispersion and dynamic-static liquid mass transfer in trickle flow reactor containing ?-SiC open-cell foams, Chemical Engineering Journal, vol.185, issue.186, p.299, 2012. ,
,
Pham-Huu, « Silicon carbide foam composite containing cobalt as a highly selective and re-usable Fischer-Tropsch synthesis catalyst, Applied Catalysis A: General, vol.397, issue.2, pp.62-72, 2011. ,
« Polydopamine-coated open cell polyurethane foams as an inexpensive, flexible yet robust catalyst support: a proof of concept, Chemical Communications, vol.52, pp.4691-4693, 2016. ,
, Compressive response of open-cell foams
, International Journal of Solids and Structures, vol.42, issue.6, pp.1355-1379, 2005.
, Polydopamine films and particles with catalytic activity, vol.301, 2018.
« Polydopamine-coated open cell polyurethane foam as an efficient and easy-to-regenerate soft structured catalytic support (S2CS) for the reduction of dye », Journal of Environmental Chemical Engineering, vol.5, issue.1, p.79, 2017. ,
,
, Grâce à cette méthode, il nous est possible, pour chaque température, de déterminer les constantes cinétiques inhérentes à chaque support
, Dans l'ordre suivant, à l'aide d'une simple régression linéaire, les constantes cinétiques en mol/s ont été obtenues : la constante cinétique kliq
, Loi d'Arrhenius
une réaction chimique, quelle que soit son ordre de réaction, est un phénomène thermiquement activé, et sa vitesse de réaction k est une fonction de la température suivant la loi d'Arrhenius (Eq, vol.9 ,
, Où Ea est l'énergie d'activation de cette réaction et R la constante des gaz parfaits
Eyring La dernière étude réalisée sur l'hydrolyse du NaBH4 porte sur l'équation d'Eyring-Polanyi ,
, Cette équation, définie ci-dessous, relie, comme la loi d'Arrhenius, la vitesse de réaction k à la température. Cependant, dans ce cas, elle découle d'un modèle théorique basé sur la thermodynamique statistique
, ?G étant l'enthalpie libre d'activation, elle peut s'exprimer en fonction de l'entropie d'activation (?S) et de l'enthalpie d'activation (?H)
, , vol.12
, , vol.13
, , vol.14
« Kit de reduction, composition reductrice et leur utilisation ,
« Valorisation catalytique du biogaz pour une energie propre et renouvelable, 2015. ,
« Hydrogen from renewable electricity: An international review of power-to-gas pilot plants for stationary applications, International Journal of Hydrogen Energy, vol.38, issue.5, pp.2039-2061, 2013. ,
« Hydrogen-storage materials for mobile applications ,
, Materials For Sustainable Energy: A Collection of Peer-Reviewed Research and Review Articles from, pp.265-270, 2011.
« Metal hydride materials for solid hydrogen storage: A review, International Journal of Hydrogen Energy, vol.32, issue.9, pp.1121-1140, 2007. ,
« Review of hydrogen storage by adsorption in carbon nanotubes, International Journal of Hydrogen Energy, vol.27, issue.2, pp.193-202, 2002. ,
« Hydrogen production through sorption-enhanced steam methane reforming and membrane technology: A review, vol.33, p.554, 2008. ,
« Hydrogen production from agricultural waste by dark fermentation: A review, International Journal of Hydrogen Energy, vol.35, pp.10660-10673, 2010. ,
« Recent progress in alkaline water electrolysis for hydrogen production and applications, Progress in Energy and Combustion Science, vol.36, issue.3, pp.307-326, 2010. ,
, Hydrogen cycle with sodium borohydride, vol.33, pp.4634-4639, 2008.
« Polydopamine-coated open cell polyurethane foams as an inexpensive, flexible yet robust catalyst support: a proof of concept, Chemical Communications, vol.52, pp.4691-4693, 2016. ,
, Procédé de modification des propriétés de surface de mousses cellulaires élastomères
,
Control of Polydopamine Surface Chemistry in Acids: A Mechanism-Based Entry to Superhydrophilic-Superoleophobic Coatings, Chemistry of Materials, vol.28, pp.4697-4705, 2016. ,
« Kinetics of hydrolysis of sodium borohydride for hydrogen production in fuel cell applications: A review, International Journal of Hydrogen Energy, vol.36, pp.9772-9790, 2011. ,
« Catalytic hydrolysis of ammonia borane for hydrogen generation using cobalt nanocluster catalyst supported on polydopamine functionalized multiwalled carbon nanotube, vol.76, p.822, 2014. ,
« Kinetics of sodium borohydride hydrolysis reaction for hydrogen generation, International Journal of Hydrogen Energy, vol.33, p.6205, 2008. ,
« Catalytic hydrolysis of sodium borohydride by a novel nickel-cobalt-boride catalyst, Journal of Power Sources, vol.173, issue.1, p.450, 2007. ,
, The Hydrolysis of Aqueous Hydroborate, vol.1, pp.608-612
« Polydopamine-coated open cell polyurethane foams as an inexpensive, flexible yet robust catalyst support: a proof of concept, Chemical Communications, vol.52, pp.4691-4693, 2016. ,
,
Bioinspired Catecholic Flame Retardant Nanocoating for Flexible Polyurethane Foams, Chemistry of Materials, vol.27, p.6784, 2015. ,
, Study on the UV-shielding and controlled-release properties of a polydopamine coating for avermectin, vol.39, pp.2752-2757, 2015.
« Polydopamine-coated open cell polyurethane foam as an efficient and easy-to-regenerate soft structured catalytic support (S2CS) for the reduction of dye », Journal of Environmental Chemical Engineering, vol.5, issue.1, p.79, 2017. ,
« Kit de reduction, composition reductrice et leur utilisation ,
,
« Borohydride functionalized polydopamine coated open cell polyurethane foam as a reusable soft structured material for reduction reactions: Application to the removal of a dye, Environmental Progress & Sustainable Energy, vol.38, issue.2, pp.329-335, 2019. ,
Adsorption of dye with carbon media supported on polyurethane open cell foam, Catalysis Today, vol.301, p.98 ,
URL : https://hal.archives-ouvertes.fr/hal-01896110
David Edouard* « Polydopamine-coated open cell polyurethane foam as an efficient and easy-toregenerate soft structured catalytic support (S2CS) for the reduction of dye, Journal of Environmental Chemical Engineering, vol.5, pp.79-85, 2017. ,
David Edouard* « Adsorption of dye with carbon media supported on polyurethane open cell foam», Catalysis Today, vol.301, pp.98-103, 2018. ,
Borohydride-functionalized polydopamine-coated open cell polyurethane foam as a reusable soft structured material for reduction reactions: application to the removal of a dye, Environmental Progress Sustainable Energy, vol.38, pp.329-335, 2019. ,
URL : https://hal.archives-ouvertes.fr/hal-01896113