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LEADER 00000cam a2200661 i 4500
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008 171002s2018 nju ob 001 0 eng
010 2017047266
019 1023628295|a1024139413|a1026245227|a1032264018|a1048164993
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020 1119446589
020 9781119446590|q(epub)
020 1119446597
020 111900425X
020 9781119004257
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020 1523115653|q(electronic bk.)
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099 eBook O'Reilly for Public Libraries
100 1 Fuller, Thomas Francis,|eauthor.
245 10 Electrochemical engineering /|cThomas F. Fuller & John N.
Harb.|h[O'Reilly electronic resource]
250 First edition.
264 1 Hoboken, NJ, USA :|bWiley,|c2018.
300 1 online resource
336 text|btxt|2rdacontent
337 computer|bn|2rdamedia
338 online resource|bnc|2rdacarrier
347 data file|2rda
500 Includes index.
500 Machine generated contents note: Preface Chapter 1
Introduction and Basic Principles (Charles Tobias) 1.1
Electrochemical Cells 1.2 Characterization of
Electrochemical Reactions 1.3 Importance of
Electrochemical Systems 1.4 Scientific Units, Constants
and Conventions 1.5 Faraday's law 1.6 Faradaic efficiency
1.7 Current Density 1.8 Potential and Ohm's law 1.9
Electrochemical Systems: Example General References
Problems Chapter 2 Cell Potential and Thermodynamics (W.M.
Latimer) 2.1 Half-cell Reactions 2.2 Cell Potential 2.3
Expression for Cell Potential 2.4 Standard Potentials 2.5
Effect of Temperature on Standard Potential 2.6 Simplified
Activity Coefficients 2.7 Use of Cell Potentials 2.8
Equilibrium constants 2.9 Pourbaix diagrams 2.10 Cells
with a Liquid Junction 2.11 Reference electrodes 2.12
Equilibrium at Electrode Interface 2.13 Potential in
Solution due to charge: Debye-Huckel theory 2.14 Activity
and Activity Coefficients 2.15 Estimation of Activity
Coefficients 2.16 Closure General References Problems
Chapter 3 Electrochemical Kinetics (Alexander N. Frumkin)
3.1 Double Layer 3.2 Impact of potential on Reaction Rate
3.3 Use of the Butler-Volmer Kinetic Expression 3.4
Reaction Fundamentals 3.5 Simplified Forms of the Butler-
Volmer Equation 3.6 Direct Fitting of the Butler-Volmer
Equation 3.7 Influence of Mass Transfer on the Reaction
Rate 3.8 Use of Kinetics Expression in Full Cells 3.9
Current Efficiency General References Problems Chapter 4
Transport (Carl Wagner) 4.1 Fick's Law 4.2 Nernst-Planck
Equation 4.3 Conservation of Material 4.4 Transference
Numbers, Mobilities, and Migration 4.5 Convective Mass
Transfer 4.6 Concentration Overpotential 4.7 Current
Distribution 4.8 Membrane transport General References
Problems Chapter 5 Electrode Structures (John Newman) 5.1
Mathematical Description of Porous Electrodes 5.2
Characterization of Porous Electrodes 5.3 Impact of Porous
Electrodes on Transport 5.4 Current Distribution in Porous
Electrodes 5.5 The Gas-Liquid Interface in Porous
Electrodes 5.6 Three Phase Electrodes 5.7 Electrode
Configurations General References Problems Chapter 6
Electro-analytical Methods and Analysis of Electrochemical
Systems (Jaroslav Heyrovsk) 6.1 Electrochemical Cells,
Instrumentation and Some Practical Issues 6.2 Overview 6.3
Step change in Potential or Current for a semi-infinite
planar electrode in a stagnant electrolyte 6.4 Electrode
Kinetics and Double Layer Charging 6.5 Cyclic Voltammetry
6.6 Stripping Analysis 6.7 Electrochemical Impedance 6.8
Rotating Disk Electrode 6.9 iR Compensation 6.10 Micro-
electrodes General References Problems Chapter 7 Battery
Fundamentals (J.B. Goodenough) 7.1 Components of a Cell
7.2 Classification of Batteries and Cell Chemistries 7.3
Theoretical Capacity and State of Charge 7.4 Cell
Characteristics and Electrochemical Performance 7.5 Ragone
Plots 7.6 Heat Generation 7.7 Efficiency of Secondary
Cells 7.8 Charge Retention and Self Discharge 7.9 Capacity
Fade in Secondary Cells General References Problems
Chapter 8 Battery Applications Cell and Battery Pack
Design (Esther Takeuchi) 8.1 Introduction to Battery
Design 8.2 Battery Layout Using a Specific Cell Design 8.3
Scaling of Cells to Adjust Capacity 8.4 Electrode and Cell
Design to Achieve Rate Capability 8.5 Cell Construction
8.6 Charging of Batteries 8.7 Use of Resistance to
Characterize Battery Performance 8.8 Battery Management
8.9 Thermal Management Systems 8.10 Mechanical
Considerations General References Problems Chapter 9 Fuel
Cell Fundamentals (Supramaniam Srinivasan) 9.1
Introduction 9.2 Types of Fuel Cells Classified by
Electrolytes 9.3 Current Voltage Characteristics and
Polarizations 9.4 Effect of Operating Conditions and
Maximum Power 9.5 Electrode Structure 9.6 Proton Exchange
Membrane Fuel Cells 9.7 Solid Oxide Fuel Cells General
References Problems Chapter 10 Fuel Cell Stack and System
Design and Applications (Francis Bacon) 10.1 Introduction
and Overview of Systems Analysis 10.2 Basic Stack Design
Concepts 10.3 Cell Stack Configurations 10.4 Basic
Construction and Components 10.5 Utilization of Fuel and
Oxidant 10.6 Flow Field Design 10.7 Water and Thermal
Management 10.8 Structural-Mechanical Considerations 10.9
Case Study General References Problems Chapter 11
Electrochemical Double Layer Capacitors (Brian E. Conway)
11.1 Capacitor Introduction 11.2 Electrical Double Layer
Capacitance 11.3 Current Voltage Relationship for
Capacitors 11.4 Porous EDLC Electrodes 11.5 Impedance
Analysis of EDLCs 11.6 Full Cell EDLC Analysis 11.7 Power
and Energy Capabilities 11.8 Cell design, practical
operation and electrochemical capacitor performance 11.9
Pseudo-capacitance General References Problems Chapter 12
Energy Storage and Conversion for Hybrid and Electric
Vehicles (Ferdinand Porsche) 12.1 Why Electric and Hybrid-
electric Systems 12.2 Driving Schedules and Power Demand
in Vehicles 12.3 Regenerative Braking 12.4 Battery
Electric Vehicle 12.5 Hybrid Vehicle Architectures 12.6
Start-stop Hybrid 12.7 Batteries for Full Hybrid-Electric
Vehicles 12.8 Fuel-cell Hybrid Systems for Vehicles
General References Problems Appendix 12A Primer on Vehicle
Dynamics Chapter 13 Electro-deposition (Richard Alkire)
13.1 Overview 13.2 Faraday's Law and Deposit Thickness
13.3 Electrodeposition Fundamentals 13.4 Formation of
Stable Nuclei 13.5 Nucleation Rates 13.6 Growth of Nuclei
13.7 Deposit Morphology 13.8 Additives 13.9 Impact of
Current Distribution 13.10 Impact of Side Reactions 13.11
Resistive Substrates General References Problems Chapter
14 Electrolysis, Redox-flow batteries, and Regenerative
Fuel Cells (Fumio Hine) 14.1 Overview of Industrial
Electrolysis 14.2 Performance Measures 14.3 Voltage Losses
and the Polarization Curve 14.4 Design of Electrochemical
Reactors for Industrial Applications 14.5 Example of
Industrial Electrolytic Processes 14.6 Thermal Management
and Cell Operation 14.7 Electrolytic Processes for a
Sustainable Future 14.8 Redox flow batteries General
References Problems Chapter 15 Semiconductors Electrodes
and Photoelectrochemical Cells (Heinz Gerischer) 15.1
Semiconductor Basics 15.2 Energy Scales 15.3 Semiconductor
/Electrolyte Interface 15.4 Current Flow in the Dark 15.5
Light Absorption 15.6 Photoelectrochemical Effects 15.7
Open-circuit Voltage for Illuminated Electrodes 15.8
Photoelectrochemical Cells General References Problems
Chapter 16 Corrosion (Ulick R. Evans) 16.1 Corrosion
Fundamentals 16.2 Thermodynamics of Corrosion Systems 16.3
Corrosion Rate for Uniform Corrosion 16.4 Localized
Corrosion 16.5 Corrosion Protection General References
Problems Appendices A Electrochemical Reactions and
Standard Potentials B Fundamental Constants C
Thermodynamic Data D Mechanics of Materials Subject Index.
504 Includes bibliographical references and index.
520 "This book covers both fundamental principles and
applications of electrochemical engineering. The goal is
to create a text for classroom instruction or independent
study at the senior undergraduate and beginning graduate
student level. It provides numerous worked out
illustrations as well as a large number of end-of chapter
problems. A supplementary solution manual has been
developed"--|cProvided by publisher.
588 0 Print version record and CIP data provided by publisher.
590 O'Reilly|bO'Reilly Online Learning: Academic/Public
Library Edition
650 0 Electrochemistry, Industrial.
650 6 Électrochimie industrielle.
650 7 Electrochemistry, Industrial|2fast
700 1 Harb, John Naim,|d1959-|eauthor.
776 08 |iPrint version:|aFuller, Thomas Francis.|tElectrochemical
engineering.|bFirst edition.|dHoboken, NJ, USA : Wiley,
2018|z9781119004257|w(DLC) 2017044994
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learning.oreilly.com/library/view/~/9781119004257/?ar
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