Handbook of Fuel Cells
Advances in Electrocatalysis, Materials, Diagnostics and Durability
A valuable addition to the established and highly acclaimed Handbook of Fuel Cells (2003).
Abbreviations and Acronyms.
PART 1: ELECTROCATALYST MATERIALS FOR LOW TEMPERATURE FUEL CELLS.
1. Platinum monolayer oxygen reduction electrocatalysts (R. R. Adzic and F. H. B. Lima).
2. Oxygen reduction on platinum bimetallic alloy catalysts (V. R. Stamenkovic and N. M. Markovic).
3. Dealloyed Pt bimetallic electrocatalysts for oxygen reduction (P. Strasser).
4. Transition metal/polymer catalysts for O2 reduction (C. M. Johnston, P. Piela, and P. Zelenay).
5. Time to move beyond transition metal N C catalysts for oxygen reduction (A. Garsuch, A. Bonakdarpour, G. Liu, R. Yang, and J. R. Dahn).
6. Catalysts for the electro oxidation of small molecules (M. Watanabe and H. Uchida).
7. Influence of size on the electrocatalytic activities of supported.
metal nanoparticles in fuel cell related reactions (Frédéric Maillard, Sergey Pronkin, and Elena R. Savinova).
8. Enzyme catalysis in biological fuel cells (Scott Calabrese Barton).
Fundamental Catalysis Models.
9. Density functional theory applied to electrocatalysis (S. Venkatachalam, and T. Jacob).
10. First principles modeling for the electrooxidation of small.
molecules (M. Neurock).
11. On the pathways of methanol and ethanol oxidation (W. Vielstich, V. A. Paganin, O. Brandao Alves, and E. G. Ciapina).
12. Reaction pathway analysis and reaction intermediate detection.
via simultaneous differential electrochemical mass spectrometry.
(DEMS) and attenuated total reflection fourier transform.
infrared spectroscopy (ATR FTIRS) (M. Heinen, Z. Jusys, and R. J. Behm).
13. Methanol oxidation on oxidized Pt surface (H. Varela, E. Sitta, and B. C. Batista).
14. Mechanistic aspects of carbon monoxide oxidation (T. Iwasita and E. G. Ciapina).
15. Platinum dissolution models and voltage cycling effects: platinum dissolution in polymer electrolyte fuel cell (PEFC) and low temperature fuel cells (K. Ota and Y. Koizumi).
16. Catalyst and catalyst support durability (F. T. Wagner, S. G. Yan, and P. T. Yu).
17. Effects of contaminants on catalyst activity (F. H. Garzon and F. A. Uribe).
PART 2: CONDUCTIVE MEMBRANES FOR LOWTEMPERATURE Fuel Cells.
18. Design rules for the improvement of the performance of hydrocarbon based membranes for proton exchange membrane fuel cells (PEMFC) (M. Gross, G. Maier, T. Fuller, S. MacKinnon and C. Gittleman).
19. High temperature polybenzimidazole based membranes (D. C. Seel, B. C. Benicewicz, L. Xiao, and T. J. Schmidt).
20. Radiation grafted proton conducting membranes (L. Gubler and G. G. Scherer).
21. Alkaline anion exchange membranes for low temperature fuel cell application (J. R. Varcoe, S. D. Poynton, and R. C. T. Slade).
22. Colloidal structure of ionomer solutions (G. Gebel).
23. Conductivity, permeability, and ohmic shorting of ionomeric membranes (C. K. Mittelsteadt and H. Liu).
24. Highly durable PFSA membranes (E. Endoh).
25. Factors influencing ionomer degradation (M. Inaba and H. Yamada).
26. Chemical and mechanical membrane degradation (W. K. Liu, S. J. C. Cleghorn, B. E. Delaney, and M. Crum).
27. Mechanical durability characterization and modeling of ionomeric membranes (Y. H. Lai and D. A. Dillard).
PART 3: MATERIALS FOR HIGH TEMPERATURE FUEL CELLS.
28. Mechanistic understanding and electrochemical modeling of mixed conducting (SOFC) electrodes (R. Merkle, J. Maier, and J. Fleig).
29. Elementary kinetic modeling of solid oxide fuel cell electrode reactions (S. B. Adler and W. G. Bessler).
30. Mechanical stability (A. Atkinson and A. J. Marquis).
31. Factors limiting the low temperature operation of SOFCs (J. David Carter, T. A. Cruse, B. J. Ingram, and M. Krumpelt).
32. New oxide cathodes and anodes (J. A. Kilner and J. T. S. Irvine).
33. New high temperature proton conductors for fuel cells and gas separation membranes (R. Haugsrud).
34. Nanoimpact on electrode and electrolyte layers with Micro Electro Mechanical System (MEMS) technique (Y. D. Premchand, A. Bieberle Hütter, H. Galinski, J. L. M. Rupp, T. M. Ryll, B. Scherrer, R. Tölke, Z. Yang, A. Harvey, A. Evans, L. Xu, and L. J. Gauckler).
35. Durability of metallic interconnects and protective coatings (M. Mogensen and K. V. Hansen).
36. Impact of impurities and interface reaction on electrochemical activity (M. Mogensen and K. V. Hansen).
37. Application of secondary ion mass spectrometry (SIMS) technique on the durability of solid oxide fuel cell (SOFC) materials (K. Yamaji, N. Sakai, H. Kishimoto, T. Horita, M. E. Brito and H. Yokokawa).
38. Durability of cathodes including Cr poisoning (N. H. Menzler, A. Mai, and D. Stöver).
39. Durable sealing concepts with glass sealants or compression seals (H. P. Buchkremer and R. Conradt).
PART 4: ADVANCED DIAGNOSTICS, MODELS, & DESIGN.
Low Temperature Fuel Cells.
40. Direct three dimensional visualization and morphological analysis of Pt particles supported on carbon by transmission electron microtomography (T. Ito, U. Matsuwaki, Y. Otsuka, G. Katagiri, M. Kato, K. Matsubara, Y. Aoyama, and H. Jinnai).
41. Design approaches for determining local current and membrane resistance in polymer electrolyte fuel cells (PEFCs) (S. A. Freunberger, M. Reum, and F. N. B?uchi).
42. Heat and water transport models for polymer electrolyte fuel cells (U. Pasaogullari).
43. Proton exchange membrane fuel cell (PEMFC) down the channel performance model (W. Gu, D. R. Baker, Y. Liu, and H. A. Gasteiger).
44. Use of neutron imaging for proton exchange membrane fuel cell (PEMFC) performance analysis and design (T. A. Trabold, J. P. Owejan, J. J. Gagliardo, D. L. Jacobson, D. S. Hussey, and M. Arif).
45. Local transient techniques in polymer electrolyte fuel cell (PEFC) diagnostics (I. A. Schneider and G. G. Scherer).
46. Proton exchange membrane fuel cell (PEMFC) flow field design for improved water management (J. S. Allen, S. Y. Son, S. H. Collicott).
47. Performance during start up of proton exchange membrane (PEM) fuel cells at subfreezing conditions (E. L. Thompson, W. Gu, and H. A. Gasteiger).
48. Performance impact of cationic contaminants (B. S. Pivovar, B. Kienitz, T. Rockward, F. Uribe, and F. Garzon).
49. Modeling the impact of cation contamination in a polymer electrolyte membrane fuel cell (T. A. Greszler, T. E. Moylan, and H. A. Gasteiger).
50. Performance modeling and cell design for high concentration methanol fuel cells (C. E. Shaffer and C. Y. Wang).
51. Design concepts and durability challenges for mini fuel cells (Shimshon Gottesfeld).
High Temperature Fuel Cells.
52. New diagnostic methods for the polarized state (T. Kawada).
53. Electrochemical impedance spectroscopy as diagnostic tool (S. H. Jensen, J. Hjelm, A. Hagen, and M. Mogensen).
54. Observation and modeling of thermal stresses in cells and cell stacks (H. Yakabe).
PART 5: PERFORMANCE DEGRADATION.
Low Temperature Fuel Cells.
55. Carbon support corrosion mechanisms and models (K. G. Gallagher, R. M. Darling, and T. F. Fuller).
56. Electrode degradation mechanisms studies by current distribution measurements (R. N. Carter, W. Gu, B. Brady, P. T. Yu, K. Subramanian, and H. A. Gasteiger).
57. Electron microscopy to study membrane electrode assembly (MEA) materials and structure degradation (M. Chatenet, L. Guetaz, and F. Maillard).
58. Proton exchange membrane fuel cell degradation: mechanisms and recent progress (T. Madden, M. Perry, L. Protsailo, M. Gummalla, S. Burlatsky, N. Cipollini, S. Motupally, and T. Jarvi).
59. Cold start durability of membrane electrode assemblies (C. Y. Wang, X. G. Yang, Y. Tabuchi, and F. Kagami).
60. Field experience with fuel cell vehicles (K. Wipke, S. Sprik, J. Kurtz, and J. Garbak).
61. Membrane and catalyst performance targets for automotive fuel cells (A. Iiyama, K. Shinohara, S. Iguchi, and A. Daimaru).
62. Field experience with portable DMFC products (J. Müller).
High Temperature Fuel Cells.
63. Overview of solid oxide fuel cell degradation (H. Yokokawa).
64. Methane reforming kinetics, carbon deposition, and redox durability of Ni/8 yttria stabilized zirconia (YSZ) anodes (E. Ivers Tiffée, H. Timmermann, A. Leonide, N. H. Menzler, and J. Malzbender).
65. Sulfur poisoning on Ni catalyst and anodes (J. B gild Hansen and J. Rostrup Nielsen).
66. Ni shorting in relation to acid base equilibrium of molten carbonate for molten cabonate fuel cell (MCFC) application (S. Mitsushima).
67. Impact of impurities on reliability of materials in solid oxide fuel cell (SOFC) stack/modules (H. Yokokawa, N. Sakai, T. Horita, and K. Yamaji).
68. Field experience with molten carbonate fuel cells (MCFCs) and solid oxide fuel cells (SOFCs) with an emphasis on degradation (H. Frey, A. Kessler, W. Münch, M. Edel and V. Nerlich).