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Intro; Preface; Contents; Abbreviations; About the Authors; Contributors; 1 Fuel Cell Technology: Policy, Features, and Applications
A Mini-review; 1.1 Introduction; 1.1.1 President Eisenhower and Energy Policy; 1.1.2 From Analytics to Policy: Department of Energy: History, Challenges, and Possible Future; 1.1.3 Current Challenges: Fossil Fuel Technology Improvement Program; 1.1.4 Department of Energy (DOE) Policies in Prior Administrations; 1.1.5 Transition to a Non-carbon Economy: The Issues; 1.1.6 The Potential Pitfalls and Hazards Toward Becoming a Non-carbon Economy
1.1.7 Economic Impacts1.1.8 Carbon Dioxide (CO2) Emission Reduction; 1.1.9 Fuel Cell Technology: Policy, Features, and Applications; 1.2 Conclusion; References; 2 Concept of Hydrogen Redox Electric Power and Hydrogen Energy Generators; 2.1 Introduction; 2.2 Theoretical Backgrounds; 2.2.1 ``Zero Power Input ́́Electrostatic Field; 2.2.2 Theoretical Power Requirement of Water Electrolysis; 2.2.3 Direct Electrostatic-to-Chemical Energy Conversion in Water Electrolysis; 2.3 Electrostatic-Induction Potential-Superposed Water Electrolysis; 2.3.1 Principle
2.4 Hydrogen Redox Electric Power and Hydrogen Energy Generators2.4.1 Suggested Generators; 2.4.2 Hydrogen Redox Electric Power Generator (HREG); 2.4.3 Hydrogen Redox Hydrogen Energy Generator; 2.5 Theories of the Onboard HREG System for Fuel Cell Vehicles with Infinite Cruising Range; 2.5.1 Outline of the Onboard HREG System; 2.5.2 Basic Equations for Infinite Cruising Range; 2.5.3 Weight Evaluation of the Onboard HREG System; 2.6 Conclusion; References; 3 Evaluation of Cell Performance and Durability for Cathode Catalysts (Platinum Supported on Carbon Blacks or Conducting Ceram...
3.1 Introduction3.2 Evaluation of Cell Performance and Durability for Pt/CBs Under the Simulated Operation of both SU/SD Cycles and Load Cycles; 3.2.1 Electrochemical and Raman Spectroscopic Evaluation of Pt/GCB Catalyst Durability for SU/SD Operation; 3.2.2 Investigation of the Corrosion of Carbon Supports in Polymer Electrolyte Fuel Cells Using Simulated SU/SD Cycling; 3.2.3 Deleterious Effects of Interim CV on Pt/CB Degradation During SU/SD Cycling; 3.2.4 Durability of Pt/GCB During Gas-Exchange SU Operation; 3.2.5 Degradation Mechanisms of CBs Under Hydrogen Passivation SU/SD Process
3.2.6 Load Cycle Durability of a Pt/GCB3.3 Synthesis and Evaluation of Cell Performance and Durability for Pt Supported on Conducting Ceramic Nanoparticles During Si...; 3.3.1 Degradation of Carbon Support and Alternative Support Materials; 3.3.2 Pt Supported on Titanium Nitride (Pt/TiN) and Carbide (Pt/TiC); 3.3.3 Pt Supported on SnO2 Catalysts; 3.3.3.1 Synthesis of Pt/SnO2 Catalyst; 3.3.3.2 Evaluation of Pt/SnO2 Catalyst by RDE; 3.3.3.3 Evaluation of Pt/SnO2 CL by MEA; 3.3.4 ``ARSM ́́Effect of Pt Supported on Ta-TiO2 Catalysts; 3.4 Conclusions; References
A Mini-review; 1.1 Introduction; 1.1.1 President Eisenhower and Energy Policy; 1.1.2 From Analytics to Policy: Department of Energy: History, Challenges, and Possible Future; 1.1.3 Current Challenges: Fossil Fuel Technology Improvement Program; 1.1.4 Department of Energy (DOE) Policies in Prior Administrations; 1.1.5 Transition to a Non-carbon Economy: The Issues; 1.1.6 The Potential Pitfalls and Hazards Toward Becoming a Non-carbon Economy
1.1.7 Economic Impacts1.1.8 Carbon Dioxide (CO2) Emission Reduction; 1.1.9 Fuel Cell Technology: Policy, Features, and Applications; 1.2 Conclusion; References; 2 Concept of Hydrogen Redox Electric Power and Hydrogen Energy Generators; 2.1 Introduction; 2.2 Theoretical Backgrounds; 2.2.1 ``Zero Power Input ́́Electrostatic Field; 2.2.2 Theoretical Power Requirement of Water Electrolysis; 2.2.3 Direct Electrostatic-to-Chemical Energy Conversion in Water Electrolysis; 2.3 Electrostatic-Induction Potential-Superposed Water Electrolysis; 2.3.1 Principle
2.4 Hydrogen Redox Electric Power and Hydrogen Energy Generators2.4.1 Suggested Generators; 2.4.2 Hydrogen Redox Electric Power Generator (HREG); 2.4.3 Hydrogen Redox Hydrogen Energy Generator; 2.5 Theories of the Onboard HREG System for Fuel Cell Vehicles with Infinite Cruising Range; 2.5.1 Outline of the Onboard HREG System; 2.5.2 Basic Equations for Infinite Cruising Range; 2.5.3 Weight Evaluation of the Onboard HREG System; 2.6 Conclusion; References; 3 Evaluation of Cell Performance and Durability for Cathode Catalysts (Platinum Supported on Carbon Blacks or Conducting Ceram...
3.1 Introduction3.2 Evaluation of Cell Performance and Durability for Pt/CBs Under the Simulated Operation of both SU/SD Cycles and Load Cycles; 3.2.1 Electrochemical and Raman Spectroscopic Evaluation of Pt/GCB Catalyst Durability for SU/SD Operation; 3.2.2 Investigation of the Corrosion of Carbon Supports in Polymer Electrolyte Fuel Cells Using Simulated SU/SD Cycling; 3.2.3 Deleterious Effects of Interim CV on Pt/CB Degradation During SU/SD Cycling; 3.2.4 Durability of Pt/GCB During Gas-Exchange SU Operation; 3.2.5 Degradation Mechanisms of CBs Under Hydrogen Passivation SU/SD Process
3.2.6 Load Cycle Durability of a Pt/GCB3.3 Synthesis and Evaluation of Cell Performance and Durability for Pt Supported on Conducting Ceramic Nanoparticles During Si...; 3.3.1 Degradation of Carbon Support and Alternative Support Materials; 3.3.2 Pt Supported on Titanium Nitride (Pt/TiN) and Carbide (Pt/TiC); 3.3.3 Pt Supported on SnO2 Catalysts; 3.3.3.1 Synthesis of Pt/SnO2 Catalyst; 3.3.3.2 Evaluation of Pt/SnO2 Catalyst by RDE; 3.3.3.3 Evaluation of Pt/SnO2 CL by MEA; 3.3.4 ``ARSM ́́Effect of Pt Supported on Ta-TiO2 Catalysts; 3.4 Conclusions; References