Fuel cell electrochemical

Ferreira PJ, Shao-Hom Y. 2007. Formation mechanism of Pt single-crystal nanoparticles in proton exchange membrane fuel cells. Electrochem Solid State Lett 10 B60-B63. [Pg.308]

Wang XP, Kumar R, Myers DJ. 2006. Effect of voltage on platinum dissolution relevance to polymer electrolyte fuel cells. Electrochem Solid State Lett 9 A225-A227. [Pg.314]

Varcoe JR, Slade RCT. 2006. An electron-beam-grafted ETFE alkaline anion-exchange membrane in metal-cation-fiee solid-state alkaline fuel cells. Electrochem Commun 8 839-843. [Pg.372]

Kurokawa H, Sholkalapper TZ, Jacobson CP, De Johghe LC, and Visco SJ. Ceria nanocoating for sulfur tolerant Ni-based anodes of solid oxide fuel cells. Electrochem... [Pg.127]

Villarreal I, Jacobson C, Leming A, Matus Y, Visco S, and De Jonghe L. Metal-supported solid oxide fuel cells. Electrochem. Solid State Lett. 2003 6 A178-A179. [Pg.278]

Mukerjee, S. and Urian, R.C., Bifunctionality in Pt alloy nanocluster electrocatalysts for enhanced methanol oxidation and CO tolerance in PEM fuel cells electrochemical and in situ synchrotron spectroscopy, Electrochim. Acta, 47, 3219, 2002. [Pg.93]

E. Peled, T. Duvdevani, A. Aharon, and A. Melman, New fuels as alternatives to methanol for direct oxidation fuel cells, Electrochem. Solid-State Lett. 4(4), A38-A41 (2001). [Pg.323]

Carter, R., Wycisk, R., Yoo, H. and Pintauro, P. N. 2002. Blended polyphosphazene/polyacrylonitrile membranes for direct methanol fuel cells. Electrochemical and Solid-State Letters 5 A195-A197. [Pg.181]

Chalkova, E., Zhou, X., Ambler, C., Hofmann, M. A., Weston, J. A., Allcock, H. R. and Lvov, S. N. 2002. Sulfonimide polyphosphazene-based H2/O2 fuel cells. Electrochemical and Solid-State letters 5 A221-A222. [Pg.181]

A. M. Kannan, V. P. Veedu, L. Munukutla, and M. N. Ghasemi-Nejhad. Nanostructured gas diffusion and catalyst layers for proton exchange membrane fuel cells. Electrochemical and Solid State Letters 10 (2007) B47-B50. [Pg.297]

K. Fatih, D. P. Wilkinson, F. Moraw, A. Ilicic, and F. Girard. Advancements in the direct hydrogen redox fuel cell. Electrochemical and Solid State Letters 11 (2008) B11-B15. [Pg.303]

Also, discussions of a number of applications of Nafion are not included in this document and are, at most, mentioned within the context of a particular study of fundamental properties. A number of these systems are simply proposed rather than in actual commercial applications. Membranes in fuel cells, electrochemical energy storage systems, chlor-alkali cells, water electrolyzers, Donnan dialysis cells, elec-trochromic devices, and sensors, including ion selective electrodes, and the use of these membranes as a strong acid catalyst can be found in the above-mentioned reviews. [Pg.299]

Wnek, G. E. Rider, J. N. Serpico, J. M. Einset, A. G. Proceedings of the First International Symposium on Proton Conducting Membrane Fuel Cells, Electrochemical Society 1995 p 247. [Pg.371]

Tower, Stephen. All About Electrochemistry. Available online. URL http //www.cheml.com/acad/webtext/elchem/. Accessed May 28, 2009. Part of a virtual chemistry textbook, this excellent resource explains the basics of electrochemistry, which is important in understanding how fuel cells work. Discussions include galvanic cells and electrodes, cell potentials and thermodynamics, the Nernst equation and its applications, batteries and fuel cells, electrochemical corrosion, and electrolytic cells and electrolysis. [Pg.162]

The generation of heat always accompanies the operation of a fuel cell. The heat is due to inefficiencies in the basic fuel-cell electrochemical reaction, crossover (residual diffusion through the fuel-cell solid-electrolyte membrane) of fuel, and electrical heating of interconnection resistances. Spatial temperature variation can occur if any of these heat-generating processes occur preferentially in different parts of the fuel cell stack. For example, non-uniform distribution of fuel across the surfaces of electrodes, different resistances between the interconnections in a stack, and variations among... [Pg.152]

Electrodialysis is by far the largest use of ion exchange membranes, principally to desalt brackish water or (in Japan) to produce concentrated brine. These two processes are both well established, and major technical innovations that will change the competitive position of the industry do not appear likely. Some new applications of electrodialysis exist in the treatment of industrial process streams, food processing and wastewater treatment systems but the total market is small. Long-term major applications for ion exchange membranes may be in the nonseparation areas such as fuel cells, electrochemical reactions and production of acids and alkalis with bipolar membranes. [Pg.422]

Petrovsky, V., Suzuki, T., Jasinski, P., and Anderson, H. U. Low-temperature Processed Anode for Solid Oxide Fuel Cells, Electrochem. and Solid-State Letters, 8, A341 (2005). [Pg.133]

What Is Known So Far about Fuel Cells—Electrochemical Energy Converters... [Pg.301]

Thus the range of applications is vast. Electroanalysis, potentiometric and voltammetric industrial electrolysis, electroplating, batteries, fuel cells, electrochemical machining, and many other related applications, including minimization of corrosion biosensors and bioelectrochemistry. [Pg.8]

A porous anode and cathode are attached to each surface of the membrane, forming a membrane-electrode assembly, similar to that employed in SPE fuel cells. Electrochemical reactions (electron transfer-l-hydrogenation) occur at the interfaces between the ion exchange membrane and electrochemically active layers of electrodes. Electrochemical reductive HDH occurred at the interfaces between the ion exchange membrane and the cathode catalyst layer when an electrical current is applied between the electrodes ... [Pg.313]

Brett DJL, Atkins S, Brandon NP, Vesovic V, Vasileiadis N, Kucemak A (2003) Localized impedance measurements along a single channel of a solid polymer fuel cell. Electrochem Solid-State Lett 6 A63-6... [Pg.262]

Setoguchi, T. et al., Effects of anode materials and fuel on anodic reaction of solid oxide fuel-cells,/. Electrochem. Soc., 139, 2875-2880 (1993). [Pg.57]

Xu, Z., Qi, Z., and Kaufman, A., Superior catalysts for proton exchange membrane fuel cells, Electrochem. Solid-State Lett., 8, A313, 2005. [Pg.301]

R.D. Farr and C.G. Vayenas, Ammonia high temperature solid electrolyte fuel cell, / Electrochem. Soc. 727 1478 (1980). [Pg.595]

This book is intended to provide a background and training suitable for application of impedance spectroscopy to a broad range of applications, such as corrosion, biomedical devices, semiconductors and solid-state devices, sensors, batteries, fuel cells, electrochemical capacitors, dielectric measurements, coatings, elec-trochromic materials, analytical chemistry, and imaging. The emphasis is on generally applicable fundamentals rather than on detailed treatment of applications. The reader is referred to other sources for discussion of specific applications of impedance. ... [Pg.540]

Holme, T.P., Pornprasertsuk, R., Prinz, F.B. Interpretation of low temperature solid oxide fuel cell electrochemical impedance spectra. J. Electrochem. Soc. 2010,157, B64-70. [Pg.233]

The electrochemical reduction of platinum sails confined to the aqueous environments of lyotropic liquid-crystalline phases leads to the deposition of platinum films[262] that have a well defined long-ranged porous nanostructure and high specific surface areas. These results suggest that the use of liquid-crystalline plating solutions could be a versatile way to create mesoporous electrodes for batteries, fuel cells, electrochemical capacitors, and sensors. [Pg.571]

K. Nisancioglu and T.M. Giir, Oxygen difusion in iron doped strontium cobaltites, in S.C. Singhal and H. Iwahara (Eds.), Proceedings of the 3rd International Symposium on Solid Oxide Fuel Cells. Electrochemical Society, Pennington, NJ, 1994, pp. 267-275. [Pg.525]

Shao, Z.-G. Hsing, I.-M. Nation membrane coated with sulfonated poly(vinyl alcohol)-Nation film for direct methanol fuel cells. Electrochem. Solid-State Lett. 2002, 5, A185. [Pg.1097]

Smith, D.S. Winnick, J. Cesium-containing electrolyte for the molten carbonate fuel cell. Electrochem. Solid State Lett. 1999, 2 (5), 207-209. [Pg.1763]

Jiang R, Kunz HR, Fenton JM (2005) Electrochemical oxidation of H2 and Hi/CO mixtures in higher temperature (Teen > 100°C) proton exchange membrane fuel cells electrochemical impedance spectroscopy. J Electrochem Soc 152(7) A1329-A1340... [Pg.100]

Ma Q, Peng R, Tian L, Meng G (2006) Direct utilization of ammonia in intermediate-temperature sohd oxide fuel cells , Electrochem. Commun., 8, 1791-1795. [Pg.563]

J.T. Muller, P.M. Urban, W.F. Holderich, K.M. Colbow, J. Zhang and D.P. Wilkinson, Electro-oxidation of dimethyl ether in a polymer-electrolyte-membrane fuel cell, J. Electrochem. Soc., 2000, 147, 4058-4060 Z. Qi, M. Hollett, A. Attia and A. Kaufman, Low temperature direct 2-propanol fuel cell, Electrochem. Solid-State Lett., 2002, 5, A129-A130. [Pg.298]

E. Brosha, S. Pacheco, P. Zelenay, F. Uribe, F. Garzon and T. Zawodzinski, "Development of Freeze-Dried Catalysts for Hydrogen and Direct Methanol Fuel Cells", Electrochemical Society Meeting, San Francisco, CA (2001). Abstract No. 322. [Pg.437]

C. K. Witham, T. I. Valdez, and S. R. Narayanan, Methanol Oxidation Activity of Co-Sputter Deposited Pt-Ru Catalysts , Proceedings of the Symposium on Direct Methanol Fuel Cells, Electrochemical Society, PV 2001-4, p.l23... [Pg.450]

Electric motor Batteries Fuel cells Electrochemical capacitors Mains electricity Diesel—electric Diesel-electric... [Pg.232]

Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...