Page 182 - Introduction to Transfer Phenomena in PEM Fuel Cells
P. 182

Bibliography     171
                           [SIE 03] SIEGEL  N.P., ELLIS  M.W., NELSON  D.J.  et al., “Single domain  PEMFC
                             model based  on agglomerate catalyst geometry”,  Journal of Power  Sources,
                             vol. 115, pp. 81–89, 2003.
                           [SIE 08] SIEGEL C., “Review of computational heat and mass transfer modeling in
                             polymer electrolyte membrane  (PEM) fuel cells”,  Energy, vol. 33, pp. 1331–
                             1352, 2008.
                           [SIN 99] SINGH  D., LU  D.M., DJILALI  N., “A two-dimensional analysis of mass
                             transport in proton exchange membrane fuel cells”,  International Journal of
                             Engineering Science, vol. 37, pp. 431–452, 1999.
                           [SME 00] SMEDLEY  S.,  “A Regenerative Zinc – Air Fuel Cell for industrial and
                             specialty vehicles”,  Fifteenth Annual Battery Conference on Applications  and
                             Advances, Long Beach, January 2000.
                           [SON 07] SONG C., TANG Y., ZHANG J.L. et al., “PEM fuel cell reaction kinetics in
                                                         o
                             the temperature range of 23–120  C”, Electrochemica Acta, vol. 52, pp. 2552–
                             2561, 2007.
                           [SOR 02] SORENSENA  T.S., KJELSTRUP  S., “A simple  Maxwell-Wagner-Butler-
                             Volmer approach to the impedance of the hydrogen electrode in a nafion fuel
                             cell”, Journal of Colloid  and Interface  Science,  vol. 248, no. 2, pp. 355–375,
                             2002.
                           [SPI 07] SPIEGEL C., Designing and building fuel cells, McGraw Hill, New York,
                             2007.
                           [SPO 02] SPOHR E., COMMER P., KORNYSHEV A.A., “Enhancing proton mobility in
                             polymer electrolyte membranes: lessons from molecular dynamics simulations”,
                             Journal of Physical Chemistry B, vol. 106, no. 41, pp. 10560–10569, 2002.
                           [SPR 91] SPRINGER T.E., ZAWODZINSKI T.A., GOTTESFELD S., “Polymer electrolyte
                             fuel cell  model”,  Journal of the Electrochemical  Society, vol. 138, no. 8,
                             pp. 2334–2342, 1991.
                           [SPR 93] SPRINGER T.E., WILSON M.S., GOTTESFELD S., “Modeling and experimental
                             diagnostics in polymer electrolyte fuel cells”,  Journal of Electrochemical
                             Society, vol. 140, no. 12, pp. 3513–3526, 1993.

                           [SRI 06] SRINIVASSAN S., Fuel Cells from fundamentals to applications, Springer,
                             Berlin, 2006.
                           [TAN 97] TANDON R., PINTAURO P.N., “Divalent/monovalent cation uptake selectivity
                             in a Nafion cation exchange  membrane: Experimental  and modeling  studies”,
                             Journal of Membrane Science, vol. 136, nos 1–2, pp. 207–219, 1997.
   177   178   179   180   181   182   183   184   185   186   187