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Fuel Cells and Hydrogen Production: A Volume in the Encyclopedia of Sustainability Science and Technology, Second Edition

Name: Fuel Cells and Hydrogen Production: A Volume in the Encyclopedia of Sustainability Science and Technology, Second Edition
Brand: Springer
Price: 3429.84 PLN
Availability: InStock

ISBN-13: 9781493977888 / Angielski / Twarda / 2018 / 1179 str.

Timothy E. Lipman; Adam Weber

Fuel Cells and Hydrogen Production: A Volume in the Encyclopedia of Sustainability Science and Technology, Second Edition

ISBN-13: 9781493977888 / Angielski / Twarda / 2018 / 1179 str.

Timothy E. Lipman; Adam Weber

cena 3429,84 zł
(netto: 3266,51 VAT: 5%)

Najniższa cena z 30 dni: 2506,10 zł

Termin realizacji zamówienia:
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Kategorie:

Technologie

Kategorie BISAC:

Technology & Engineering > Power Resources - General
Science > Chemia - Fizyczna
Science > Chemistry - Industrial & Technical

Wydawca:

Springer

Seria wydawnicza:

Encyclopedia of Sustainability Science and Technology

Język:

Angielski

ISBN-13:

9781493977888

Rok wydania:

2018

Wydanie:

2019

Numer serii:

000801611

Ilość stron:

1179

Waga:

2.88 kg

Wymiary:

26.16 x 19.05 x 7.37

Oprawa:

Twarda

Wolumenów:

Part I: Fuel Cells

1. Fuel Cells, Introduction
2. Alkaline Membrane Fuel Cells
3. Direct Hydrocarbon Solid Oxide Fuel Cells
4. Fuel Cell Comparison to Alternate Technologies
5. Fuel Cell Types and Their Electrochemistry
6. Fuel Cells (SOFC): Alternative Approaches (Electroytes, Electrodes, Fuels)
7. Membrane Electrolytes, from Perfluoro Sulfonic Acid (PFSA) to Hydrocarbon Ionomers
8. Molten Carbonate Fuel Cells
9. PEM Fuel Cell Materials: Costs, Performance and Durability
10. PEM Fuel Cells and Platinum-Based Electrocatalysts
11. PEM Fuel Cells, Materials and Design Development Challenges
12. Phosphoric Acid Fuel Cells for Stationary Applications
13. Polybenzimidazole Fuel Cell Technology
14. Polymer Electrolyte (PE) Fuel Cell Systems
15. Polymer Electrolyte Membrane (PEM) Fuel Cells, Automotive Applications
16. Polymer Electrolyte Membrane Fuel Cells (PEM-FC) and Non-noble Metal Catalysts for Oxygen Reduction
17. Proton Exchange Membrane Fuel Cells: High-Temperature, Low-Humidity Operation
18. Solid Oxide Fuel Cell Materials: Durability, Reliability and Cost
19. Solid Oxide Fuel Cells
20. Solid Oxide Fuel Cells, Marketing Issues
21. Solid Oxide Fuel Cells, Sustainability Aspects

Part II: Hydrogen Production Science and Technology

22. Advances on Inorganic Membrane Reactors for Production of Hydrogen
24. Biohydrogen Production
25. Biohydrogen Production from Agricultural Residues
26. Electrochemical Hydrogen Production
27. Genetic Optimization of Microalgae for Hydrogen Production
28. Hydrogen Production from Biological Sources
29. Hydrogen Production from High-Temperature Fuel Cells
30. Hydrogen Production Science and Technology
31. Hydrogen Production through Pyrolysis
32. Hydrogen via Direct Solar Production
33. Hydrogen Production through Electrolysis
34. Photo-catalytic Hydrogen Production

Index

Timothy E. Lipman is an energy and environmental technology, economics, and policy researcher and lecturer with the University of California - Berkeley. He is serving as Co-Director for the campus' Transportation Sustainability Research Center (TSRC), based at the Institute of Transportation Studies, and also as Director of the Northern California Center for Alternative Transportation Fuels and Advanced Vehicle Technologies (NorthCAT -- see "northcat.org") effort. Tim's research focuses on electric-drive vehicles, fuel cell technology, combined heat and power systems, biofuels, renewable energy, and electricity and hydrogen energy systems infrastructure.

Lipman received his Ph.D. degree in Environmental Policy Analysis with the Graduate Group in Ecology at UC Davis (1999). He also has received an M.S. degree in the technology track of the Graduate Group in Transportation Technology and Policy, also at UC Davis (1998), and a B.A. from Stanford University (1990). His Ph.D. dissertation titled "Zero-Emission Vehicle Scenario Cost Analysis Using A Fuzzy Set-Based Framework" received the University of California Transportation Center's 'Charlie Wootan' Ph.D. dissertation award for 1999. He is also a 2005 Climate Change Fellow with the Woods Institute at Stanford University, and he also received a 2004 Institute of Transportation Engineers service award, a 1998 NSF IGERT teaching fellowship, a 1997 University of California Transportation Center Dissertation Grant, a 1996 ENO Foundation Fellowship, a 1995 University of California Transportation Center Dissertation Grant, and a 1994 Chevron Foundation Fellowship. A native of Golden, Colorado, he graduated Cum Laude from Colorado Academy in 1986.

Most of his research projects are related to the transformation of energy systems to support motor vehicles and buildings, examining how both incremental and "leap frog" technologies can be applied to reduce greenhouse gas emissions and other negative environmental and social impacts of energy use. A central concept for his research is that the electrification of the transportation sector can realize synergy with a concentrated effort to reduce the carbon intensity of the electrical grid, yielding benefit for the electricity sector as well as the expanded use of electricity, hydrogen, and biofuels.

Adam Z. Weber holds B.S. and M.S. degrees from Tufts University, the latter

under the guidance of Professor Maria Flytzani-Stephanopoulos. Next, he

earned his Ph.D. at University of California, Berkeley, in Chemical Engineering

under the guidance of John Newman. His dissertation work focused on the

fundamental investigation and mathematical modeling of water management

in polymer-electrolyte fuel cells.

Dr. Weber continued his study of water and thermal management in

polymer-electrolyte fuel cells at Lawrence Berkeley National Laboratory,

where he is now a staff scientist and program manager for Hydrogen and

Fuel Cell Technologies. His current research involves understanding and

optimizing fuel-cell performance and lifetime including component and

ionomer structure/function studies using advanced modeling and diagnostics,

understanding flow batteries for grid-scale energy storage, and analysis of

solar-fuel generators where he is a Thrust coordinator at the Joint Center for

Artificial Photosynthesis (JCAP).

Dr. Weber has coauthored over 110 peer-reviewed articles and 10 book

chapters on fuel cells, flow batteries, and related electrochemical devices;

developed many widely used models for fuel cells and their components;

and has been invited to present his work at various international and national

meetings. He is the recipient of a number of awards including a Fulbright

scholarship to Australia, the 2008 Oronzio and Niccolò De Nora Foundation

Prize on Applied Electrochemistry of the International Society of Electrochemistry,

the 2012 Supramaniam Srinivasan Young Investigator Award of the

Energy Technology Division of the Electrochemical Society, a 2012 Presidential

Early Career Award for Scientists and Engineers (PECASE), the 2014

CharlesW. Tobias Young Investigator Award of the Electrochemical Society, a

Kavli Fellow in 2014, and the 2016 Sir William Grove Award from the

International Association for Hydrogen Energy. He is a Fellow of The Electrochemical

Society.

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