High-temperature electrolysis : from fundamentals to applications /
edited by Werner Sitte, Rotraut Merkle.
- 1 online resource (various pagings) : illustrations (some color).
- [IOP release $release] IOP ebooks. [2022 collection] .
- IOP (Series). Release 22. IOP ebooks. 2022 collection. .
"Version: 20230101"--Title page verso.
Includes bibliographical references.
1. High-temperature electrolysis--general overview / Mogens Bjerg Mogensen, Francesco Mondi and Gurli Mogensen -- 2. Electrolyte materials for solid oxide electrolysis cells / Stephen J. Skinner, Chen-Yu Tsai, Per Hjalmarrson, Robert Leah and Subhasish Mukerjee -- 3. Anode materials for solid oxide electrolysis cells / Christian Berger and Andreas Egger -- 4. Cathode materials for solid oxide electrolysis cells / Peter Holtappels, John T.S. Irvine and Shu Wang -- 5. Interconnects and coatings / Belma Talic, Elena Stefan and Yngve Larring -- 6. Electrode kinetics / Alexander K. Opitz and Andreas Nenning -- 7. Cell architectures / Anke Hagen and Ming Chen -- 8. Metal-supported cells / Martin Bram and Norbert H. Menzler -- 9. Advanced data analysis / Dino Klotz, Sebastian Dierickx, Jochen Joos and Andr�e Weber -- 10. Long-term stack tests / Qingping Fang and Norbert H. Menzler -- 11. Proton and mixed proton/hole-conducting materials for protonic ceramic electrolysis cells / Rotraut Merkle -- 12. Thermodynamics, transport, and electrochemistry in protonic ceramic electrolysis cells / Huayang Zhu, Sandrine Ricote and Robert J. Kee -- 13. Tubular protonic ceramic electrolysis cells and direct hydrogen compression / Einar V�llestad -- 14. Planar protonic ceramic electrolysis cells for H2 production and CO2 conversion / Fan Liu and Chuancheng Duan -- 15. Co-solid oxide electrolysis and methanation / Andreas Krammer and Markus Lehner -- 16. CO2 electrolysis / Christopher Graves, Theis L Skafte and S�ren H�jgaard Jensen -- 17. Power-to-ammonia for fertilizers, chemicals, and as an energy vector / John B�gild Hansen -- 18. SOEC-based production of e-fuels via the Fischer-Tropsch route / Dorela Dhamo, Dominik Hess, Michael Rubin and Roland Dittmeyer -- 19. Reversible solid oxide cell systems as key elements of achieving flexibility in future energy systems / David Paczona, Christoph Sejkora and Thomas Kienberger -- 20. Economic aspects of power-to-gas / Hans B�ohm and Robert Tichler.
There is a strong need to store electrical energy from fluctuating renewable energy sources such as solar or wind and to decarbonize transport and industry. High-temperature electrolysis is expected to contribute significantly to reach these goals. This reference text provides a detailed guide, including the fundamental and materials aspects of solid oxide and protonic ceramic electrolysis cells at stack and system levels, as well as recent developments. Applications discussed include the production of green hydrogen as well as the combination of high-temperature electrolysis with other processes for the synthesis of ammonia, methane or e-fuels. Highly relevant to the field of renewable energy supply and conversion, the text provides a comprehensive and accessible reference for researchers, engineers, and graduate students from various disciplines.
Materials scientists, energy researchers and researchers involved in solid state electrochemistry.
Mode of access: World Wide Web.
System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader.
Professor Dr. Werner Sitte is full professor of Physical Chemistry and a full professor at Montanuniversitaet Leoben, Austria. His research interests concern transport and defect chemistry in ionic solids as well as applications towards solid oxide and protonic fuel and electrolyser cells. He is an associate editor of the journal Solid State Ionics and is on the scientific board of International Conferences on Solid State Ionics. Dr. Rotraut Merkle is a scientist at the Max Planck Institute for Solid State Research, Germany. Her research is dedicated to point defect formation and transport in ionic solids, reaction kinetics at oxide surfaces, transport at grain boundaries, and extends to solid oxide and protonic ceramic fuel and electrolysis cells. She is involved in EMRS, SSI and SSPC conference organization, and is an editor for the Solid State Ionics journal.
9780750339513 9780750339506
10.1088/978-0-7503-3951-3 doi
High temperature electrolysis.
Direct energy conversion.
Energy storage.
Renewable energy sources.
Energy conversion & storage.
TECHNOLOGY & ENGINEERING / Power Resources / Alternative & Renewable.
TK2896 / .H548 2023eb
621.31/24
"Version: 20230101"--Title page verso.
Includes bibliographical references.
1. High-temperature electrolysis--general overview / Mogens Bjerg Mogensen, Francesco Mondi and Gurli Mogensen -- 2. Electrolyte materials for solid oxide electrolysis cells / Stephen J. Skinner, Chen-Yu Tsai, Per Hjalmarrson, Robert Leah and Subhasish Mukerjee -- 3. Anode materials for solid oxide electrolysis cells / Christian Berger and Andreas Egger -- 4. Cathode materials for solid oxide electrolysis cells / Peter Holtappels, John T.S. Irvine and Shu Wang -- 5. Interconnects and coatings / Belma Talic, Elena Stefan and Yngve Larring -- 6. Electrode kinetics / Alexander K. Opitz and Andreas Nenning -- 7. Cell architectures / Anke Hagen and Ming Chen -- 8. Metal-supported cells / Martin Bram and Norbert H. Menzler -- 9. Advanced data analysis / Dino Klotz, Sebastian Dierickx, Jochen Joos and Andr�e Weber -- 10. Long-term stack tests / Qingping Fang and Norbert H. Menzler -- 11. Proton and mixed proton/hole-conducting materials for protonic ceramic electrolysis cells / Rotraut Merkle -- 12. Thermodynamics, transport, and electrochemistry in protonic ceramic electrolysis cells / Huayang Zhu, Sandrine Ricote and Robert J. Kee -- 13. Tubular protonic ceramic electrolysis cells and direct hydrogen compression / Einar V�llestad -- 14. Planar protonic ceramic electrolysis cells for H2 production and CO2 conversion / Fan Liu and Chuancheng Duan -- 15. Co-solid oxide electrolysis and methanation / Andreas Krammer and Markus Lehner -- 16. CO2 electrolysis / Christopher Graves, Theis L Skafte and S�ren H�jgaard Jensen -- 17. Power-to-ammonia for fertilizers, chemicals, and as an energy vector / John B�gild Hansen -- 18. SOEC-based production of e-fuels via the Fischer-Tropsch route / Dorela Dhamo, Dominik Hess, Michael Rubin and Roland Dittmeyer -- 19. Reversible solid oxide cell systems as key elements of achieving flexibility in future energy systems / David Paczona, Christoph Sejkora and Thomas Kienberger -- 20. Economic aspects of power-to-gas / Hans B�ohm and Robert Tichler.
There is a strong need to store electrical energy from fluctuating renewable energy sources such as solar or wind and to decarbonize transport and industry. High-temperature electrolysis is expected to contribute significantly to reach these goals. This reference text provides a detailed guide, including the fundamental and materials aspects of solid oxide and protonic ceramic electrolysis cells at stack and system levels, as well as recent developments. Applications discussed include the production of green hydrogen as well as the combination of high-temperature electrolysis with other processes for the synthesis of ammonia, methane or e-fuels. Highly relevant to the field of renewable energy supply and conversion, the text provides a comprehensive and accessible reference for researchers, engineers, and graduate students from various disciplines.
Materials scientists, energy researchers and researchers involved in solid state electrochemistry.
Mode of access: World Wide Web.
System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader.
Professor Dr. Werner Sitte is full professor of Physical Chemistry and a full professor at Montanuniversitaet Leoben, Austria. His research interests concern transport and defect chemistry in ionic solids as well as applications towards solid oxide and protonic fuel and electrolyser cells. He is an associate editor of the journal Solid State Ionics and is on the scientific board of International Conferences on Solid State Ionics. Dr. Rotraut Merkle is a scientist at the Max Planck Institute for Solid State Research, Germany. Her research is dedicated to point defect formation and transport in ionic solids, reaction kinetics at oxide surfaces, transport at grain boundaries, and extends to solid oxide and protonic ceramic fuel and electrolysis cells. She is involved in EMRS, SSI and SSPC conference organization, and is an editor for the Solid State Ionics journal.
9780750339513 9780750339506
10.1088/978-0-7503-3951-3 doi
High temperature electrolysis.
Direct energy conversion.
Energy storage.
Renewable energy sources.
Energy conversion & storage.
TECHNOLOGY & ENGINEERING / Power Resources / Alternative & Renewable.
TK2896 / .H548 2023eb
621.31/24