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" Nanostructured materials for next-generation energy storage and conversion : "
Fan Li, Sajid Bashir, Jingbo Louise Liu, editors.
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BL
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882649
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Nanostructured materials for next-generation energy storage and conversion : : fuel cells /\ Fan Li, Sajid Bashir, Jingbo Louise Liu, editors.
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| Publication Statement
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Berlin :: Springer,, [2018]
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, ©2018
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1 online resource (xliv, 556 pages) :: illustrations (some color)
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| ISBN
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3662563630
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: 3662563649
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: 9783662563632
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: 9783662563649
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9783662563632
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Includes bibliographical references and index.
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| Contents
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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.
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1.1.7 Economic Impacts; 1.1.8 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.
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2.4 Hydrogen Redox Electric Power and Hydrogen Energy Generators; 2.4.1 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 ...
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3.1 Introduction; 3.2 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.
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3.2.6 Load Cycle Durability of a Pt/GCB; 3.3 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.
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| Abstract
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The energy crisis and pollution have posed significant risks to the environment, transportation, and economy over the last century. Thus, green energy becomes one of the critical global technologies and the use of nanomaterials in these technologies is an important and active research area. This book series presents the progress and opportunities in green energy sustainability. Developments in nanoscaled electrocatalysts, solid oxide and proton exchange membrane fuel cells, lithium ion batteries, and photovoltaic techniques comprise the area of energy storage and conversion. Developments in carbon dioxide (CO2) capture and hydrogen (H2) storage using tunable structured materials are discussed. Design and characterization of new nanoscaled materials with controllable particle size, structure, shape, porosity and band gap to enhance next generation energy systems are also included. The technical topics covered in this series are metal organic frameworks, nanoparticles, nanocomposites, proton exchange membrane fuel cell catalysts, solid oxide fuel cell electrode design, trapping of carbon dioxide, and hydrogen gas storage.
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| Subject
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Fuel cells.
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Nanostructured materials.
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Fuel cells.
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Nanostructured materials.
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Nanotechnology.
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TECHNOLOGY ENGINEERING-- Mechanical.
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| Dewey Classification
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621.31/2429
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| LC Classification
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TK2931
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| Added Entry
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Bashir, Sajid,1967-
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Li, Fan
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Liu, Jingbo Louise
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| Parallel Title
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Fuel cells
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