ISBN | 9780470258439(0470258438) |
---|---|
Âʼö | 576ÂÊ |
¾ð¾î | English |
Å©±â | 196(W) X 236(H) (mm) |
ÆÇ | 2/E |
Á¦º»ÇüÅ | Hardcover |
ÃѱǼö | 1±Ç |
Textual Format | Textbooks, Lower level |
¸®µùÁö¼ö Level | Scholarly/Undergraduate |
Preface | |
Acknowledgments | |
Nomenclature | |
Fuel Cell Principles | |
Introduction | |
What is a Fuel Cell? | |
A Simple Fuel Cell | |
Fuel Cell Advantages | |
Fuel Cell Disadvantages | |
Fuel Cell Types | |
Basic Fuel Cell Operation | |
Fuel Cell Performance | |
Characterization and Modeling | |
Fuel Cell Technology | |
Fuel Cells and the Environment | |
Chapter Summary | |
Chapter Exercises | |
Fuel Cell Thermodynamics | |
Thermodynamics Review | |
Heat Potential of a Fuel: Enthalpy of Reaction | |
Work Potential of a Fuel: Gibbs Free Energy | |
Predicting Reversible Voltage of a Fuel Cell Under Non-Standard-State Conditions | |
Fuel Cell Efficiency | |
Thermal and Mass Balances in Fuel Cells | |
Chapter Summary | |
Chapter Exercises | |
Fuel Cell Reaction Kinetics | |
Introduction to Electrode Kinetics | |
Why Charge Transfer Reactions Have an Activation Energy | |
Activation Energy Determines Reaction Rate | |
Calculating Net Rate of a Reaction | |
Rate of reaction at Equilibrium: Exchange current Density | |
Potential of a Reaction at Equilibrium: Galvani Potential | |
Potential and Rate: ButlerVolmer Equation | |
Exchange Currents and Electrocatalysis: How to Improve Kinetic Performance | |
Simplified Activation Kinetics: Tafel Equation | |
Different Fuel Cell Reactions Produce Different Kinetics | |
Catalyst-Electrode Design | |
Quantum Mechanics: Framework for Understanding Catalysis in Fuel Cells | |
Connecting the ButlerVolmer and Nernst Equations (Optional | |
Chapter Summary | |
Chapter Exercises | |
Fuel Cell Charge Transport | |
Charges Move in Response to Forces | |
Charge Transport Results in a Voltage Loss | |
Characteristics of Fuel Cell Charge Transport Resistance | |
Physical Meaning of Conductivity | |
Review of Fuel Cell Electrolyte Classes | |
More on Diffusivity and Conductivity (Optional | |
Why Electrical Driving Forces Dominate Charge Transport (Optional | |
Quantum MechanicsBased Simulaton of Ion Conduction in Oxide Electrolytes (Optional | |
Chapter Summary | |
Chapter Exercises | |
Fuel Cell Mass Transport | |
Transport in Electrode Versus Flow Structure | |
Transport in Electrode: Diffusive Transport | |
Transport in Flow Structures: Convective Transport | |
Chapter Summary | |
Chapter Exercises | |
Fuel Cell Modeling | |
Putting It All Together: A Basic Fuel Cell Model | |
A 1D Fuel Cell Model | |
Fuel Cell Models Based on Computational Fluid Dynamics (Optional | |
Chapter Summary | |
Chapter Exercises | |
Fuel Cell Characterization | |
What Do We Want to Characterize? | |
Overview of Characterization Techniques | |
In Situ Electrochemical Characterization Techniques | |
Ex Situ Characterization Techniques | |
Chapter Summary | |
Chapter Exercises | |
Fuel Cell Technology | |
Overview Of Fuel Cell Types | |
Introduction | |
Phosphoric Acid Fuel Cell | |
Polymer Electrolyte Membrane Fuel Cell | |
Alkaline Fuel Cell | |
Molten Carbonate Fuel Cell | |
Solid Oxide Fuel Cell | |
Other Fuel Cells | |
Summary Comparison | |
Chapter Summary | |
Chapter Exercises | |
Pemfc And Sofc Materials | |
PEMFC Electrolyte Materials | |
PEMFC Electrode/Catalyst Materials | |
SOFC Electrolyte Materials | |
SOFC Electrode/Catalyst Materials | |
Material Stability, Durability, And Lifetime | |
Chapter Summary | |
Chapter Exercises | |
Overview Of Fuel Cell Systems | |
Fuel Cell Stack (Fuel Cell Subsystem | |
The Thermal Management Subsystem | |
Fuel Delivery/Processing Subsystem | |
Power Electronics Subsystem | |
Case Study of Fuel Cell System Design: Stationary Combined Heat and Power Systems | |
Case Study of Fuel Cell System Design: Sizing A Portable Fuel Cell | |
Chapter Summary | |
Chapter Exercises | |
Fuel Processing Subsystem Design | |
Fuel Reforming Overview | |
WaterGas Shift Reactors | |
Carbon Monoxide Clean-Up | |
Reformer and Processor Efficiency Losses | |
Reactor Design for Fuel Reformers and Processors | |
Chapter Summary | |
Chapter Exercises | |
Thermal Management Subsystem Design | |
Overview of Pinch Point Analysis Steps | |
Chapter Summary | |
Chapter Exercises | |
Fuel Cell System Design | |
Fuel Cell Design Via Computational Fluid Dynamics | |
Fuel Cell System Design: a Case Study | |
Chapter Summary | |
Chapter Exercises | |
Environmental Impact Of Fuel Cells | |
Life Cycle Assessment | |
Important Emissions For LCA | |
Emissions Related to Global Warming | |
Emissions Related to Air Pollution | |
Analyzing Entire Scenarios with LCA | |
Chapter Summary | |
Chapter Exercises | |
Appendixes | |
Constants And Conversions | |
Thermodynamic Data | |
Standard Electrode Potentials At 25 ?C | |
Quantum Mechanics | |
Atomic Orbitals | |
Postulates of Quantum Mechanics | |
One-Dimensional Electron Gas | |
Analogy to Column Buckling | |
Hydrogen Atom | |
Periodic Table Of The Elements | |
Suggested Further Reading | |
Important Equations | |
Bibliography | |
Index | |
Table of Contents provided by Publisher. All Rights Reserved. |
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