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Advanced Ceramics for Energy Conversion and Storage [Pehme köide]

Edited by (Institute of Energy and Climate research (IEK-1): Materials Synthesis and Processing, Forschungszentrum Julich, Germany)
  • Formaat: Paperback / softback, 746 pages, kõrgus x laius: 229x152 mm, kaal: 1190 g
  • Sari: Elsevier Series in Advanced Ceramic Materials
  • Ilmumisaeg: 15-Nov-2019
  • Kirjastus: Elsevier / The Lancet
  • ISBN-10: 0081027265
  • ISBN-13: 9780081027264
Teised raamatud teemal:
Advanced Ceramics for Energy Conversion and StorageSuurem pilt
  • Formaat: Paperback / softback, 746 pages, kõrgus x laius: 229x152 mm, kaal: 1190 g
  • Sari: Elsevier Series in Advanced Ceramic Materials
  • Ilmumisaeg: 15-Nov-2019
  • Kirjastus: Elsevier / The Lancet
  • ISBN-10: 0081027265
  • ISBN-13: 9780081027264
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780081027264.html
Märksõnad:
In order to enable an affordable, sustainable, fossil-free future energy supply, research activities on relevant materials and related technologies have been intensified in recent years, Advanced Ceramics for Energy Conversion and Storage describes the current state-of-the-art concerning materials, properties, processes, and specific applications. Academic and industrial researchers, materials scientists, and engineers will be able to get a broad overview of the use of ceramics in energy applications, while at the same time become acquainted with the most recent developments in the field.

With chapters written by recognized experts working in their respective fields the book is a valuable reference source covering the following application areas: ceramic materials and coatings for gas turbines; heat storage and exchange materials for solar thermal energy; ceramics for nuclear energy; ceramics for energy harvesting (thermoelectrics, piezoelectrics, and sunlight conversion); ceramic gas separation membranes; solid oxide fuel cells and electrolysers; and electrochemical storage in battery cells.

Advanced Ceramics for Energy Conversion and Storage offers a sound base for understanding the complex requirements related to the technological fields and the ceramic materials that make them possible. The book is also suitable for people with a solid base in materials science and engineering that want to specialize in ceramics.
Contributors ix
Preamble xv
Introduction: The future of our energy supply relies on ceramic materials xvii
Part One Ceramics for power generation
1 High-temperature materials for power generation in gas turbines
3(60)
Emine Bakan
Daniel E. Mack
Georg Matter
Robert Vaben
Jacques Lamon
Nitin P. Padture
1 Background and technical relevance
3(4)
2 High-temperature structural materials
7(17)
3 Coatings
24(27)
4 Outlook
51(1)
References
51(11)
Further reading
62(1)
2 Ceramics in the nuclear fuel cycle
63(26)
Simon C. Middleburgh
William E. Lee
Michael J.D. Rushton
1 Uranium and thorium ore
65(1)
2 Nuclear fuel manufacture and operation
66(11)
3 Burnable absorbers and neutron control materials
77(2)
4 Barrier ceramics
79(1)
5 Moderating ceramics
80(1)
6 Waste and geological disposal
80(3)
References
83(4)
Further reading
87(2)
3 Ceramics for concentrated solar power (CSP): From thermophysical properties to solar absorbers
89(42)
Danielle Ngoue
Antoine Grosjean
Laurie Di Giacomo
Sehastien Quoizola
Audrey Soum-Glaude
Laurent Thomas
Yasmine Lalau
Reine Reoyo-Prats
Bernard Claudet
Olivier Faugeroux
Cedric Leray
Adrien Toutant
Jean-Yves Peroy
Alain Ferriere
Gabriel Olalde
1 Introduction
89(4)
2 High-temperature air-stable metal/ceramic solar selective absorber multilayer coatings based on silicon carbide
93(9)
3 Performances and capabilities of materials under high solar flux
102(10)
4 Thermomechanical design and proof of concept of a high-temperature pressurized solar ceramic receiver
112(7)
5 Conclusion
119(2)
Acknowledgments
121(1)
References
122(5)
Further reading
127(4)
Part Two Ceramics for energy harvesting
4 Oxide thermoelectrics: From materials to module
131(26)
Nini Pryds
Rasmus Bjørk
1 Introduction and applications of thermoelectricity
131(6)
2 TE oxide materials (n- and p-type)
137(2)
3 TE generator performance and models
139(6)
4 Segmented TE generators
145(3)
5 Contact resistance
148(4)
6 Outlook
152(1)
References
152(5)
5 Piezoelectrics
157(50)
Hwang-Pill Kim
Woo-Seok Kang
Chang-Hyo Hong
Geon-Ju Lee
Gangho Choi
Jaechan Ryu
Wook Jo
1 Introduction
157(17)
2 Textured piezoelectric ceramics
174(10)
3 Quenching
184(3)
4 Functions and applications of piezoelectric ceramics
187(15)
5 Perspectives
202(1)
References
203(3)
Further reading
206(1)
6 Functional metal oxide ceramics as electron transport medium in photovoltaics and photo-electrocatalysis
207(70)
Alexander Mollmann
Danny Bialuschewski
Thomas Fischer
Yasuhiro Tachibana
Sanjay Mathur
1 Introduction
207(3)
2 Nanostructured metal oxide ceramics as electron transport medium for PEC water splitting reactions
210(17)
3 Nanostructured metal oxide ceramics as electron transport medium in inorganic-organic hybrid perovskite solar cells
227(13)
4 Transient characterization of charge carrier dynamics in ceramics
240(16)
5 Conclusions and perspectives
256(2)
Acknowledgments
258(1)
References
258(15)
Further reading
273(4)
Part Three Ceramics for electrochemical applications
7 Fundamentals of electrical conduction in ceramics
277(44)
Steffen Grieshammer
Roger A. De Souza
1 Introduction to electrical conductivity
277(3)
2 Concentration of charge carriers
280(17)
3 Mobility of charge carriers
297(21)
References
318(1)
Further reading
319(2)
8 Gas separation ceramic membranes
321(66)
Julio Garcia-Fayos
Jose M. Serra
Mieke W.J. Luiten-Olieman
Wilhelm A. Meulenberg
1 Introduction
321(3)
2 Types of ceramic-based membranes for gas separation
324(16)
3 Ionic transport ceramic membranes
340(17)
4 Catalytic membrane reactors
357(14)
5 Concluding remarks
371(1)
Acknowledgments
372(1)
References
372(13)
Further reading
385(2)
9 Solid oxide fuel and electrolysis cells
387(162)
Christian Lenser
David Udomsilp
Norbert H. Menzler
Peter Holtappels
Takaya Fujisaki
Leonard Kwati
Hiroshige Matsumoto
Antonio Gianfranco Sabato
Federico Smeacetto
Andreas Chrysanthou
Sebastian Molin
1 Introduction
387(12)
2 Oxygen-ion-conducting electrolytes
399(9)
3 Fuel electrode materials for oxygen-ion conductors
408(17)
4 Air electrode materials for oxygen-ion conductors
425(18)
5 Proton conductors and adjacent electrodes
443(21)
6 Sealing
464(18)
7 Ceramic coatings for interconnects
482(12)
8 Degradation
494(16)
9 Summary and outlook
510(9)
Acknowledgments
519(1)
References
519(28)
Further reading
547(2)
10 Ceramics for electrochemical storage
549(162)
Yulia Arinicheva
Michael Wolff
Sandra Lobe
Christian Dellen
Dina Fattakhova-Rohlfing
Olivier Guillon
Daniel Bohm
Florian Zoller
Richard Schmuch
Lie Li
Martin Winter
Evan Adamczyk
Valerie Prolong
1 Introduction: Overview of battery technologies
549(14)
2 Ceramic anodes for Li and Na-ion batteries
563(30)
3 Ceramic cathodes for Li and Na-ion batteries
593(47)
4 Ceramics as separators and solid electrolytes
640(23)
5 Outlook
663(2)
References
665(42)
Further reading
707(4)
Index 711
Professor Olivier Guillon studied materials science and engineering at the Ecole des Mines dAlès and completed his PhD on the non-linear behaviour of ferroelectric ceramics in France. He then joined, as a post-doc researcher, the group of Professor Jürgen Rödel at TU Darmstadt, Germany. Focusing on constrained sintering, he also visited the group of Professor Raj Bordia at the University of Washington (USA) and established in Darmstadt a DFG funded Emmy Noether Group on new ceramic processes. After spending two years at the Friedrich Schiller University of Jena as Professor of Mechanics of Functional Materials, he became Director at the Institute of Energy and Climate Research - Materials Synthesis and Processing (Forschungszentrum Jülich, Germany) and Professor at the RWTH Aachen University in 2014. His research interests encompass thermal barrier coatings and ceramic matrix composites, solid oxide fuel/electrolysis cells, gas separation membranes and batteries. The development and processing of solid electrolytes for lithium and sodium ions and their integration into all-solid-state batteries play a key role in this regard.