Applications catalysis

Attaching the catalyst molecules to the electrode surface presents an obvious advantage for synthetic and sensor applications. Catalysis can then be viewed as a supported molecular catalysis. It is the object of the next section. A distinction is made between monolayer and multilayer coatings. In the former, only chemical catalysis may take place, whereas both types of catalysis are possible with multilayer coatings, thanks to their three-dimensional structure. Besides substrate transport in the bathing solution, the catalytic responses are then under the control of three main phenomena electron hopping conduction, substrate diffusion, and catalytic reaction. While several systems have been described in which electron transport and catalysis are carried out by the same redox centers, particularly interesting systems are those in which these two functions are completed by two different molecular systems. [Pg.252]

These ordered array materials find interest not only in catalysis, but in several other applications, from optical materials, sensors, low-k materials, ionic conductors, photonic crystals, and bio-mimetic materials.Flowever, with respect to these applications, catalysis requires additional specific characteristics, such as the presence of a thermally stable nanostructure, the minimization of grain boundaries where side reactions may occur, and the presence of a porous structure which guarantees a high surface area coupled to low heat and mass transfer limitations. An ordered assembly of ID nanostructures for oxide materials could, in principle, meet these different requirements. [Pg.84]

J. D. Carter, et al., Fuel processing for fuel cell systems in transportation and portable power applications. Catalysis Today, 2002, 77, 3-16. [Pg.46]

Knowledge of the surface dynamics of a solid has recently allowed significant progress in many academic and scientific fields adsorption (gas-solid interaction), wettability (liquid-solid), adhesion (solid-solid), and in applications catalysis [1,2], membrane [3,4], friction [5-8], blending [9,10],... [Pg.385]

Cavani F, Trifiro F, Vaccari A. Hydrotalcite-type anionic clays Preparation, properties and applications. Catalysis Today. 1991 11 (2) 173—301. [Pg.304]

Shekhawat, D., Berry, D.A., Gardner, T.H., and Spivey, J.J. Catalytic reforming of liquid hydrocarbon fuels for fuel cell applications. Catalysis, 2006, 19, 184. [Pg.117]

Fierro, V., Klouz, V., Akdim, O., and Mirodatos, C. Oxidative reforming of biomass derived ethanol for hydrogen production in fuel cell applications. Catalysis Today, 2002, 75 (1—4), 141. [Pg.125]

Eriksson, S., Nilsson, M., Boutonnet, M., and Jaras, S. Partial oxidation of methane over rhodium catalysts for power generation applications. Catalysis Today, 2005, 100, 447. [Pg.154]

Ma, X.L., Sun, L., and Song, C.S. A new approach to deep desulfurization of gasoline, diesel fuel and jet fuel by selective adsorption for ultra-clean fuels and for fuel cell applications. Catalysis Today, 2002, 77, 107. [Pg.305]

Moon, D.J. and Ryu, J.W. Molybdenum carbide water-gas shift catalyst for fuel cell-powered vehicles applications. Catalysis Letters, 2004, 92, 17. [Pg.328]

Korotkikh, O. and Farrauto, R.J. Selective catalytic oxidation of CO in H2 Fuel cell applications. Catalysis Today, 2000, 62, 249. [Pg.354]

Ahluwalia, R.K., Zhang, Q., Chmielewski, D.J., Lauzze, K.C., and Inbody, M.A. Performance of CO preferential oxidation reactor with noble-metal catalyst coated on ceramic monolith for onboard fuel processing applications. Catalysis Today, 2005, 99, 271. [Pg.355]

Saint-Just, J. der Kinderen, J. Catalytic combustion from reaction mechanism to commercial applications. Catalysis Today 1996, 29, 387-395. [Pg.370]

Phenomenal progress has been made in the synthesis of nanostruetured materials in the last decade. A deeper understanding of the formation mechanisms has been established and it is now possible to synthesize these materials in a reproducible way. Modification of the properties of these materials should now pave the way for the use of these materials for conventional applications (catalysis, separation, adsorption, etc.) and for novel applications in the fields of solar energy conversion, electronics, hydrogen generation, etc. [Pg.1834]

The limited residence time available for reaction in an extruder is often a disadvantage. Although about 30 min is the maximum, less than 5-min residence time is usually observed in commercial extruders with realistic barrel lengths. Thus, the kinetics of the desired chemical reaction must be such that about 1-5 min would be the sufficient time for complete reaction, although when applicable, catalysis frequently shortens the time required for reaction. [Pg.2538]

Choudhary T V, Goodman D W (2002), CO-free fuel processing for fuel cell applications , Catalysis Today, 77, 65-78. [Pg.561]

M. Krumpelt, T. R. Krause, J. D. Carter, J. P. Kopasz, and S. Ahmed, Fuel Processing for Fuel Cell Systems in Transportation and Portable Power Applications, Catalysis Today (submitted for publication). [Pg.336]

E. M. Johansson, D. Papadias, P.O. Thevenin, A.G. Ersson, R. Gabrielsson, P.G. Menon, P.H. Bjornbom and S.G. Jaras, in Catalytic Combustion for Gas Turbine Applications, Catalysis-Specialist Periodical Reports, Volume 14, Royal Society of Chemistry, Cambridge 2001... [Pg.290]

M. Guiver, Properties of SPEEK based PEMs for fuel-cell application. Catalysis Today 82 (2003) 213-222. [Pg.83]

Silicon-oxygen-based cage compounds for electronic applications, catalysis, storage systems, e.g. for hydrogen, nanostructured silicates ( nanotubes , microreactors). [Pg.3]

However, it recently became desirable to be able to synthesize porous silica nanoparticles, having both a narrow monodispersity and a well-defined pore size, for a wide range of applications catalysis, chromatography, controlled release, custom-designed pigments, and optical hosts. [Pg.736]

D. J. Moon J. W. Ryu. Molybdenum Carbide Water-Gas Shift Catalyst for Enel Cell-Powered Vehicles Applications. Catalysis Letters. 92, 17-24, 2004. [Pg.161]

National Research Council, Commission on Physical Sciences, Mathematics, and Applications, Catalysis Looks to the Future, National Academies Press, Washington, DC (1992)... [Pg.16]

Copper has a long history in chemistry. Nevertheless, Al-heterocycUc carbene (NHC)-copper systems have been known and used only these last 20 years since Arduengo et al. reported the first NHC-copper system in 1993 [1]. Since then, the NHC-copper chemistry has undergone continuous expansion with the synthesis of new complexes (well-defined systems, hydrides, hydroxides, and cationic species) and the development of various applications (catalysis, transme-talation reagents, antitumor reagents, etc.). NHC-copper systems have become an example of a best-seller in organometallic chemistry. [Pg.223]

Top domains for multiple applications of micro- and nanoparticles with magnetic properties are biomedical applications, catalysis and industrial applications. [Pg.156]

Colombo M, Koltsakis G, Nova I, Tronconi E (2011) Modelling the ammonia adsorption-desorption process over an Fe-zeolite catalyst for SCR automotive applications. Catalysis... [Pg.423]

S. Kaliuguine, S. D. Mikhailenko, K. P. Wang, P. Xing, G. P. Robertson, M. D. Guiver, Properties of SPEEK based PEMs for fuel cell application. Catalysis Today 82, 213-222 (2003)... [Pg.220]

F. Cavani, F. Trifiro, and A. Vaccari, Hydrotalcite-type anionic clays preparation, properties and applications. Catalysis today, 11(2) 173-301, 1991. [Pg.159]

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