Wentworth
Institute of Technology
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Electrocatalysts for Low Temperature Fuel Cells : Fundamentals and Recent Trends.
Published 2017Table of Contents: “…Chapter 4: Direct Hydrocarbon Low-temperature Fuel Cell4.1 Introduction; 4.2 Direct Methanol Fuel Cell; 4.3 Direct Ethanol Fuel Cell; 4.4 Direct Ethylene Glycol Fuel Cell; 4.5 Direct Formic Acid Fuel Cell; 4.6 Direct Glucose Fuel Cell; 4.7 Commercialization Status of DHFC; 4.8 Conclusions and Outlook; References; Chapter 5: The Oscillatory Electrooxidation of Small Organic Molecules; 5.1 Introduction; 5.2 In Situ and Online Approaches; 5.3 The Effect of Temperature; 5.4 Modified Surfaces; 5.5 Conclusions and Outlook; Acknowledgments; References.…”
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Electrocatalysts for Low Temperature Fuel Cells : Fundamentals and Recent Trends.
Published 2017Table of Contents: “…Chapter 4: Direct Hydrocarbon Low-temperature Fuel Cell4.1 Introduction; 4.2 Direct Methanol Fuel Cell; 4.3 Direct Ethanol Fuel Cell; 4.4 Direct Ethylene Glycol Fuel Cell; 4.5 Direct Formic Acid Fuel Cell; 4.6 Direct Glucose Fuel Cell; 4.7 Commercialization Status of DHFC; 4.8 Conclusions and Outlook; References; Chapter 5: The Oscillatory Electrooxidation of Small Organic Molecules; 5.1 Introduction; 5.2 In Situ and Online Approaches; 5.3 The Effect of Temperature; 5.4 Modified Surfaces; 5.5 Conclusions and Outlook; Acknowledgments; References.…”
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Direct alcohol fuel cells for portable applications : fundamentals, engineering and advances / Alexandra M.F.R. Pinto, Vânia B. Oliveira, Daniela S. Falcão.
Published 2018Table of Contents: Full text (Wentworth users only)
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Exergy for A Better Environment and Improved Sustainability 1 Fundamentals / edited by Fethi Aloui, Ibrahim Dincer.
Published 2018Table of Contents: “…Parametric Exergetic Investigation of a Direct Formic Acid Fuel Cell System -- Chapter66. Experimental and Numerical Investigations of a Small Turbojet Engine with the Aid of Exergy -- Chapter67. …”
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Electrocatalysis of direct methanol fuel cells : from fundamentals to applications / edited by Hansan Liu and Jiujun Zhang.
Published 2009Table of Contents: “…. -- 14.2 Electrocatalysis of Direct Formic Acid Fuel Cells. -- 14.3 Electrocatalysis of Direct Ethanol Fuel Cells. -- 14.4 Electrocatalysis of Direct Hydrazine Fuel Cells. -- 14.5 Other Direct Liquid Fueled Fuel Cells. -- 14.6 Summary. -- References. -- Index.…”
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Fuel cell systems explained / Andrew L Dicks, Griffith University, Brisbane, Australia, David A J Rand, CSIRO Energy Flagship, Melbourne, Australia.
Published 2018Table of Contents: “…5.2 System Designs -- 5.2.1 Circulating Electrolyte Solution -- 5.2.2 Static Electrolyte Solution -- 5.2.3 Dissolved Fuel -- 5.2.4 Anion-Exchange Membrane Fuel Cells -- 5.3 Electrodes -- 5.3.1 Sintered Nickel Powder -- 5.3.2 Raney Metals -- 5.3.3 Rolled Carbon -- 5.3.4 Catalysts -- 5.4 Stack Designs -- 5.4.1 Monopolar and Bipolar -- 5.4.2 Other Stack Designs -- 5.5 Operating Pressure and Temperature -- 5.6 Opportunities and Challenges -- Further Reading -- Chapter 6 Direct Liquid Fuel Cells -- 6.1 Direct Methanol Fuel Cells -- 6.1.1 Principles of Operation -- 6.1.2 Electrode Reactions with a Proton-Exchange Membrane Electrolyte -- 6.1.3 Electrode Reactions with an Alkaline Electrolyte -- 6.1.4 Anode Catalysts -- 6.1.5 Cathode Catalysts -- 6.1.6 System Designs -- 6.1.7 Fuel Crossover -- 6.1.8 Mitigating Fuel Crossover: Standard Techniques -- 6.1.9 Mitigating Fuel Crossover: Prospective Techniques -- 6.1.10 Methanol Production -- 6.1.11 Methanol Safety and Storage -- 6.2 Direct Ethanol Fuel Cells -- 6.2.1 Principles of Operation -- 6.2.2 Ethanol Oxidation, Catalyst and Reaction Mechanism -- 6.2.3 Low-Temperature Operation: Performance and Challenges -- 6.2.4 High-Temperature Direct Ethanol Fuel Cells -- 6.3 Direct Propanol Fuel Cells -- 6.4 Direct Ethylene Glycol Fuel Cells -- 6.4.1 Principles of Operation -- 6.4.2 Ethylene Glycol: Anodic Oxidation -- 6.4.3 Cell Performance -- 6.5 Formic Acid Fuel Cells -- 6.5.1 Formic Acid: Anodic Oxidation -- 6.5.2 Cell Performance -- 6.6 Borohydride Fuel Cells -- 6.6.1 Anode Catalysts -- 6.6.2 Challenges -- 6.7 Application of Direct Liquid Fuel Cells -- Further Reading -- Chapter 7 Phosphoric Acid Fuel Cells -- 7.1 High-Temperature Fuel-Cell Systems -- 7.2 System Design -- 7.2.1 Fuel Processing -- 7.2.2 Fuel Utilization -- 7.2.3 Heat-Exchangers -- 7.2.3.1 Designs -- 7.2.3.2 Exergy Analysis -- 7.2.3.3 Pinch Analysis.…”
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Fuel cell systems explained / Andrew L Dicks, Griffith University, Brisbane, Australia, David A J Rand, CSIRO Energy Flagship, Melbourne, Australia.
Published 2018Table of Contents: “…5.2 System Designs -- 5.2.1 Circulating Electrolyte Solution -- 5.2.2 Static Electrolyte Solution -- 5.2.3 Dissolved Fuel -- 5.2.4 Anion-Exchange Membrane Fuel Cells -- 5.3 Electrodes -- 5.3.1 Sintered Nickel Powder -- 5.3.2 Raney Metals -- 5.3.3 Rolled Carbon -- 5.3.4 Catalysts -- 5.4 Stack Designs -- 5.4.1 Monopolar and Bipolar -- 5.4.2 Other Stack Designs -- 5.5 Operating Pressure and Temperature -- 5.6 Opportunities and Challenges -- Further Reading -- Chapter 6 Direct Liquid Fuel Cells -- 6.1 Direct Methanol Fuel Cells -- 6.1.1 Principles of Operation -- 6.1.2 Electrode Reactions with a Proton-Exchange Membrane Electrolyte -- 6.1.3 Electrode Reactions with an Alkaline Electrolyte -- 6.1.4 Anode Catalysts -- 6.1.5 Cathode Catalysts -- 6.1.6 System Designs -- 6.1.7 Fuel Crossover -- 6.1.8 Mitigating Fuel Crossover: Standard Techniques -- 6.1.9 Mitigating Fuel Crossover: Prospective Techniques -- 6.1.10 Methanol Production -- 6.1.11 Methanol Safety and Storage -- 6.2 Direct Ethanol Fuel Cells -- 6.2.1 Principles of Operation -- 6.2.2 Ethanol Oxidation, Catalyst and Reaction Mechanism -- 6.2.3 Low-Temperature Operation: Performance and Challenges -- 6.2.4 High-Temperature Direct Ethanol Fuel Cells -- 6.3 Direct Propanol Fuel Cells -- 6.4 Direct Ethylene Glycol Fuel Cells -- 6.4.1 Principles of Operation -- 6.4.2 Ethylene Glycol: Anodic Oxidation -- 6.4.3 Cell Performance -- 6.5 Formic Acid Fuel Cells -- 6.5.1 Formic Acid: Anodic Oxidation -- 6.5.2 Cell Performance -- 6.6 Borohydride Fuel Cells -- 6.6.1 Anode Catalysts -- 6.6.2 Challenges -- 6.7 Application of Direct Liquid Fuel Cells -- Further Reading -- Chapter 7 Phosphoric Acid Fuel Cells -- 7.1 High-Temperature Fuel-Cell Systems -- 7.2 System Design -- 7.2.1 Fuel Processing -- 7.2.2 Fuel Utilization -- 7.2.3 Heat-Exchangers -- 7.2.3.1 Designs -- 7.2.3.2 Exergy Analysis -- 7.2.3.3 Pinch Analysis.…”
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