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Hydrogen Energy Conversion and Management
- 1st Edition - September 24, 2023
- Editors: Mohammad Masud Kamal Khan, Abul Kalam Azad, Amanullah Maung Than Oo
- Language: English
- Paperback ISBN:9 7 8 - 0 - 4 4 3 - 1 5 3 2 9 - 7
- eBook ISBN:9 7 8 - 0 - 4 4 3 - 1 6 1 3 3 - 9
Hydrogen Energy Conversion and Management presents the challenges and solutions to the use of hydrogen as the significant energysource of the future. With a focus on the theory and… Read more
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Request a sales quoteHydrogen Energy Conversion and Management presents the challenges and solutions to the use of hydrogen as the significant energy
source of the future. With a focus on the theory and recent technological developments, this book comprehensively addresses the
production, storage, and real-world applications of hydrogen.
Divided into four sections, Section 1 provides an overview of hydrogen technology, including environmental sustainability and the
fundamentals of the hydrogen economy and future energy security. Section 2 examines the latest technologies for efficient and costeffective
production of hydrogen, while Section 3 examines the latest technologies for efficient storage and transportation. Finally, Section 4 critically analyzes the challenges, solutions, and implementation prospects for a hydrogen-based fuel economy.
Hydrogen Energy Conversion and Management is an invaluable resource for researchers and practitioners involved in the hydrogen economy and for graduates and research students on multidisciplinary subjects involving renewable energy.
source of the future. With a focus on the theory and recent technological developments, this book comprehensively addresses the
production, storage, and real-world applications of hydrogen.
Divided into four sections, Section 1 provides an overview of hydrogen technology, including environmental sustainability and the
fundamentals of the hydrogen economy and future energy security. Section 2 examines the latest technologies for efficient and costeffective
production of hydrogen, while Section 3 examines the latest technologies for efficient storage and transportation. Finally, Section 4 critically analyzes the challenges, solutions, and implementation prospects for a hydrogen-based fuel economy.
Hydrogen Energy Conversion and Management is an invaluable resource for researchers and practitioners involved in the hydrogen economy and for graduates and research students on multidisciplinary subjects involving renewable energy.
- Examines the latest technological developments in hydrogen production, storage, and transportation alongside technological solutions to their real-world applications.
- Provides step-by-step guidance on new methods, processes, and simulations, supported by experimental data, including hydrogen production from waste.
- Focuses on green hydrogen generation methods, including novel approaches in production and storage and practical applications.
Researchers working in the field of hydrogen energy conversion, Graduate-level students and professional engineers working in the area of hydrogen and more broadly in renewable energy
- Cover image
- Title page
- Table of Contents
- Copyright
- Contributors
- Preface
- Section I. Overview of hydrogen energy
- Chapter 1. Evolution of hydrogen energy and its potential opportunities around the globe
- 1. Introduction
- 2. Hydrogen key characteristics
- 3. Hydrogen economy
- 4. Hydrogen global demands
- 5. Future hydrogen application scope
- 6. Green hydrogen's role in energy transition
- 7. Hydrogen safety
- 8. Summary
- Chapter 2. Hydrogen deployment potential in Colombia: an opportunity to decarbonize and diversify the economy
- 1. Introduction
- 2. Hydrogen production potential in Colombia
- 3. Prospects for hydrogen demand in Colombia
- 4. Hydrogen export potential
- 5. Conclusions
- Section II. Production and conversion
- Chapter 3. Hydrogen production by electrolysis: A sustainable pathway
- 1. Introduction
- 2. Scientific methods of hydrogen production
- 3. Why would electrolysis be the best option?
- 4. Conclusions
- Chapter 4. Hydrogen production from municipal solid waste using gasification method
- 1. Introduction
- 2. Hydrogen energy
- 3. MSW gasification model for H2 production
- 4. Results and analysis
- 5. Conclusion
- Chapter 5. Techno-economic prospects of green hydrogen production
- 1. Introduction
- 2. Methods of study
- 3. Green hydrogen production processes
- 4. Economic analysis
- 5. Conclusion
- Chapter 6. Energy and exergy analysis of blue hydrogen production and conversion
- 1. Introduction
- 2. Hydrogen production technologies from hydrocarbon feedstock
- 3. Gasification process for hydrogen production from solid feeds
- 4. Hydrogen separation processes
- 5. Energy and exergy analysis of hydrogen production processes
- 6. The role of CO2 capture, utilization and storage
- 7. Conclusion
- Chapter 7. Proton exchange membrane fuel cell system integration, modeling, and simulation for energy-efficient electric vehicle
- 1. Introduction
- 2. State of the art of fuel cell electric vehicles
- 3. Methodology
- 4. Results
- 5. Discussion
- 6. Conclusion
- Chapter 8. Techno-economic analysis of a heat and power combination system based on hybrid photovoltaic-fuel cell systems using hydrogen as an energy vector
- 1. Introduction
- 2. System description
- 3. Methodology
- 4. Results and discussion
- 5. Conclusions
- 6. Appendix
- Section III. Storage and transportation
- Chapter 9. Hydrogen energy storage and transportation challenges: A review of recent advances
- 1. Introduction
- 2. Hydrogen production technologies
- 3. Hydrogen storage systems
- 4. Hydrogen transportation challenges
- 5. Hydrogen energy applications
- 6. Conclusion
- Chapter 10. Application of multiphase heat transfer for efficient hydrogen storage and recovery
- 1. Introduction
- 2. Low temperature metal hydride reactors
- 3. High-temperature metal hydride reactors
- 4. Conclusions
- Chapter 11. Large-scale hydrogen storage using underground hydrogen storage, metal hydride storage, and other emerging technologies
- 1. Introduction
- 2. Overview of large-scale hydrogen storage technologies
- 3. District-level hydrogen penetrated-IES planning method considering large-scale hydrogen storage
- 4. Regional hydrogen penetrated-IES planning method considering gas pipeline retrofit and expansion
- 5. Conclusion
- Section IV. Applications and transition
- Chapter 12. Hydrogen-based automotive applications: a promising future
- 1. Introduction
- 2. Background
- 3. Hydrogen as an energy vector
- 4. Automotive applications
- 5. Future challenges and trends
- 6. Conclusion
- Chapter 13. Hydrogen use in high-efficiency compression ignition engines
- 1. Introduction
- 2. Combustion fundamentals
- 3. Implementation of H2 in CI engines
- 4. Practical applications
- 5. Summary and directions for future research and development
- Index
- No. of pages: 498
- Language: English
- Edition: 1
- Published: September 24, 2023
- Imprint: Elsevier
- Paperback ISBN: 9780443153297
- eBook ISBN: 9780443161339
MK
Mohammad Masud Kamal Khan
Professor Masud Khan is currently the Head of the Mechanical Engineering Department at Auckland University of Technology, New
Zealand. He previously served as the Head of Department and School, Deputy Dean Research, School of Engineering and Technology
at Central Queensland University, Australia. His research and teaching interests are in thermofluids engineering, energy-efficient and
environmentally sustainable technologies including production, storage, and performance assessment of renewable energy, hydrogen,
and biofuels produced from various feedstock. He has made significant contributions in research providing fundamental solutions to
many complex projects, engineering education, and academic leadership. He spent three visiting professorial appointments in Canada
and the United States of America. He has over 410 publications including 3 edited books and 27 book chapters.
Affiliations and expertise
School of Engineering, Computer and Mathematical Sciences, Auckland University of Technology, Auckland-1010, New ZealandAA
Abul Kalam Azad
Dr. Kalam Azad is a Lecturer at CQUniversity, Melbourne, Australia. His field of interest is renewable energy technologies, energy
conversion, and their relevant industrial applications. He has published over a hundred scientific articles, including six edited books
with Elsevier. The recognition of his research has been proved through a high number of citations and h-index both in Scopus and Google
Scholar. He also works as a Section Editor: Sustainable Energy and Energies journal. Currently, he is a member of different professional bodies throughout the world.
Affiliations and expertise
School of Engineering and Technology Central Queensland University, Melbourne Campus, VIC-3000, AustraliaAO
Amanullah Maung Than Oo
Professor Aman Oo is currently the Dean of Engineering at Macquarie University. Previously, he was the Dean and Head of School of
Engineering, Computer and Mathematical Sciences at Auckland University of Technology, New Zealand, and the Dean of Engineering at
Deakin University, Australia. He is a Professor of Electrical Engineering and has made significant research contributions to electrical
power engineering and renewable energy, engineering education, and leadership. He has published more than 350 scholarly peerreviewed
articles. Aman has research interests and expertise in microgrid and energy storage system integration, hydrogen, smart
grid communication, power system stability and control, energy management and efficiency, protection and security of smart grids,
sustainable operation, and control of microgrids as well as in engineering education.
Affiliations and expertise
School of Engineering, Macquarie University, Sydney, NSW-2109, AustraliaRead Hydrogen Energy Conversion and Management on ScienceDirect