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The Resource Analytical modeling of fuel cells, Andrei A. Kulikovsky

Analytical modeling of fuel cells, Andrei A. Kulikovsky

Label
Analytical modeling of fuel cells
Title
Analytical modeling of fuel cells
Statement of responsibility
Andrei A. Kulikovsky
Creator
Author
Subject
Language
eng
Summary
Analytical Modelling of Fuel Cells, Second Edition, is devoted to the analytical models that help us understand the mechanisms of cell operation. The book contains equations for the rapid evaluation of various aspects of fuel cell performance, including cell potential, rate of electrochemical reactions, rate of transport processes in the cell, and temperature fields in the cell, etc. Furthermore, the book discusses how to develop simple physics-based analytical models. A new chapter is devoted to analytical models of PEM fuel cell impedance, a technique that exhibits explosive growth potential. Finally, the book contains Maple worksheets implementing some of the models discussed. Includes simple physics-based equations for the fuel cell polarization curveProvides analytical solutions for fuel cell impedanceIncludes simple equations for calculation of temperature shapes in fuel cellsIntroduces physical descriptions of the basic transport and kinetic phenomena in fuel cells of various types
Member of
Cataloging source
N$T
http://library.link/vocab/creatorName
Kulikovsky, Andrei A
Dewey number
621.31/2429015118
Illustrations
illustrations
Index
index present
LC call number
TK2931
LC item number
.K85 2019
Literary form
non fiction
Nature of contents
  • dictionaries
  • bibliography
http://library.link/vocab/subjectName
Fuel cells
Label
Analytical modeling of fuel cells, Andrei A. Kulikovsky
Instantiates
Publication
Antecedent source
unknown
Bibliography note
Includes bibliographical references and index
Carrier category
online resource
Carrier category code
  • cr
Carrier MARC source
rdacarrier
Color
multicolored
Content category
text
Content type code
  • txt
Content type MARC source
rdacontent
Contents
  • Front Cover; Analytical Modeling of Fuel Cells; Copyright; Contents; Preface to the First Edition; Preface to the Second Edition; Introduction; Dimensionless variables; Maple codes; 1 Fuel cell basics; 1.1 Fuel cell thermodynamics; 1.1.1 The physics of the fuel cell effect; 1.1.2 Open-circuit voltage; 1.1.3 Nernst equation; 1.1.4 Temperature dependence of open-circuit voltage; 1.2 Potentials in a fuel cell; 1.3 Rate of electrochemical reactions; 1.3.1 Butler-Volmer equation; 1.3.2 Butler-Volmer and Nernst equations; 1.3.3 Tafel equation; 1.4 Mass transport in fuel cells
  • 1.4.1 Overview of mass transport processes1.4.2 Stoichiometry and utilization; 1.4.3 Quasi-2D approximation; 1.4.4 Mass conservation equation in the channel; 1.4.5 Flow velocity in the channel; 1.4.6 Mass transport in gas diffusion/backing layers; Fick's diffusion; Stefan-Maxwell diffusion; 1.4.7 Mass transport in catalyst layers; 1.4.8 Proton and water transport in membrane; 1.5 Sources of heat in a fuel cell; 1.6 Types of cells considered in this book; 1.6.1 Polymer electrolyte fuel cells (PEFCs); 1.6.2 Direct methanol fuel cells (DMFCs); 1.6.3 Solid oxide fuel cells (SOFCs)
  • 2 Catalyst layer performance2.1 Basic equations; 2.1.1 The general case; 2.1.2 First integral; 2.2 Ideal oxygen and proton transport; 2.3 Ideal oxygen transport; 2.3.1 Basic equations; 2.3.2 Integral of motion; 2.3.3 Equation for proton current; 2.3.4 Low cell current; 2.3.5 High cell current; 2.3.6 Polarization curve; 2.3.7 Condition of negligible oxygen transport loss; 2.4 Ideal proton transport; 2.4.1 Basic equations; 2.4.2 The x-shapes and polarization curve; 2.4.3 Large zeta; 2.4.4 Small zeta; 2.5 Optimal oxygen diffusion coef cient; 2.5.1 Reduction of the full system
  • 2.5.2 Optimal oxygen diffusivity2.6 Complete polarization curve of a PEMFC; 2.6.1 Model equations; 2.7 Gradient of catalyst loading; 2.7.1 Model; 2.7.2 Polarization curve; 2.8 DMFC cathode and mixed potential; 2.8.1 Model; Basic equations; Boundary conditions; First integral; 2.8.2 Mixed potential; 2.9 DMFC anode; 2.9.1 The rate of methanol oxidation; 2.9.2 Basic equations and the conservation law; 2.9.3 The general form of the polarization curve; 2.9.4 Small variation of overpotential in the active layer; 2.9.5 Active layer of variable thickness; 2.10 Heat balance in the catalyst layer
  • 2.10.1 Heat transport equation in the CL2.10.2 Reduction to boundary condition; 2.10.3 Solution to the heat transport equation; 2.11 Remarks on Chapter 2; 3 One-dimensional model of a fuel cell; 3.1 Voltage loss due to oxygen transport in the GDL; 3.2 One-dimensional polarization curve of a cell; 3.2.1 Fast oxygen transport in the CCL; 3.2.2 General equation for the PEMFC polarization curve; Polarization curve tting; 3.3 One-dimensional model of DMFC; 3.3.1 Feed molecule concentration in the active layers; Methanol; Oxygen; 3.3.2 One-dimensional polarization curve of DMFC
Dimensions
unknown
Edition
Second edition.
Extent
1 online resource (xvi, 366 pages)
File format
unknown
Form of item
online
Isbn
9780444642226
Level of compression
unknown
Media category
computer
Media MARC source
rdamedia
Media type code
  • c
Other physical details
illustrations (some color)
http://library.link/vocab/ext/overdrive/overdriveId
9780444642905
Quality assurance targets
not applicable
Reformatting quality
unknown
Sound
unknown sound
Specific material designation
remote
System control number
(OCoLC)1100071216
Label
Analytical modeling of fuel cells, Andrei A. Kulikovsky
Publication
Antecedent source
unknown
Bibliography note
Includes bibliographical references and index
Carrier category
online resource
Carrier category code
  • cr
Carrier MARC source
rdacarrier
Color
multicolored
Content category
text
Content type code
  • txt
Content type MARC source
rdacontent
Contents
  • Front Cover; Analytical Modeling of Fuel Cells; Copyright; Contents; Preface to the First Edition; Preface to the Second Edition; Introduction; Dimensionless variables; Maple codes; 1 Fuel cell basics; 1.1 Fuel cell thermodynamics; 1.1.1 The physics of the fuel cell effect; 1.1.2 Open-circuit voltage; 1.1.3 Nernst equation; 1.1.4 Temperature dependence of open-circuit voltage; 1.2 Potentials in a fuel cell; 1.3 Rate of electrochemical reactions; 1.3.1 Butler-Volmer equation; 1.3.2 Butler-Volmer and Nernst equations; 1.3.3 Tafel equation; 1.4 Mass transport in fuel cells
  • 1.4.1 Overview of mass transport processes1.4.2 Stoichiometry and utilization; 1.4.3 Quasi-2D approximation; 1.4.4 Mass conservation equation in the channel; 1.4.5 Flow velocity in the channel; 1.4.6 Mass transport in gas diffusion/backing layers; Fick's diffusion; Stefan-Maxwell diffusion; 1.4.7 Mass transport in catalyst layers; 1.4.8 Proton and water transport in membrane; 1.5 Sources of heat in a fuel cell; 1.6 Types of cells considered in this book; 1.6.1 Polymer electrolyte fuel cells (PEFCs); 1.6.2 Direct methanol fuel cells (DMFCs); 1.6.3 Solid oxide fuel cells (SOFCs)
  • 2 Catalyst layer performance2.1 Basic equations; 2.1.1 The general case; 2.1.2 First integral; 2.2 Ideal oxygen and proton transport; 2.3 Ideal oxygen transport; 2.3.1 Basic equations; 2.3.2 Integral of motion; 2.3.3 Equation for proton current; 2.3.4 Low cell current; 2.3.5 High cell current; 2.3.6 Polarization curve; 2.3.7 Condition of negligible oxygen transport loss; 2.4 Ideal proton transport; 2.4.1 Basic equations; 2.4.2 The x-shapes and polarization curve; 2.4.3 Large zeta; 2.4.4 Small zeta; 2.5 Optimal oxygen diffusion coef cient; 2.5.1 Reduction of the full system
  • 2.5.2 Optimal oxygen diffusivity2.6 Complete polarization curve of a PEMFC; 2.6.1 Model equations; 2.7 Gradient of catalyst loading; 2.7.1 Model; 2.7.2 Polarization curve; 2.8 DMFC cathode and mixed potential; 2.8.1 Model; Basic equations; Boundary conditions; First integral; 2.8.2 Mixed potential; 2.9 DMFC anode; 2.9.1 The rate of methanol oxidation; 2.9.2 Basic equations and the conservation law; 2.9.3 The general form of the polarization curve; 2.9.4 Small variation of overpotential in the active layer; 2.9.5 Active layer of variable thickness; 2.10 Heat balance in the catalyst layer
  • 2.10.1 Heat transport equation in the CL2.10.2 Reduction to boundary condition; 2.10.3 Solution to the heat transport equation; 2.11 Remarks on Chapter 2; 3 One-dimensional model of a fuel cell; 3.1 Voltage loss due to oxygen transport in the GDL; 3.2 One-dimensional polarization curve of a cell; 3.2.1 Fast oxygen transport in the CCL; 3.2.2 General equation for the PEMFC polarization curve; Polarization curve tting; 3.3 One-dimensional model of DMFC; 3.3.1 Feed molecule concentration in the active layers; Methanol; Oxygen; 3.3.2 One-dimensional polarization curve of DMFC
Dimensions
unknown
Edition
Second edition.
Extent
1 online resource (xvi, 366 pages)
File format
unknown
Form of item
online
Isbn
9780444642226
Level of compression
unknown
Media category
computer
Media MARC source
rdamedia
Media type code
  • c
Other physical details
illustrations (some color)
http://library.link/vocab/ext/overdrive/overdriveId
9780444642905
Quality assurance targets
not applicable
Reformatting quality
unknown
Sound
unknown sound
Specific material designation
remote
System control number
(OCoLC)1100071216

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