Flexibility-Oriented Operation of Integrated Power and Gas Networks and Low-Carbon Technologies Under Clean Energy Transition
- 1 Edición - 17 de junio de 2026
- Última edición
- Editores: Mohammad Taghi Ameli, Mohammad Mehdi Amiri, Hossein Ameli, Sasan Azad, Mohammadreza Daneshvar, Meysam Qadrdan, Goran Strbac
- Idioma: Inglés
Flexibility-Oriented Operation of Integrated Power and Gas Networks and Low-Carbon Technologies Under Clean Energy Transition examines the critical role that integrated gas and el… Leer más
Descripción
Descripción
Flexibility-Oriented Operation of Integrated Power and Gas Networks and Low-Carbon Technologies Under Clean Energy Transition examines the critical role that integrated gas and electricity networks play in achieving a sustainable, low-carbon energy future. Sections cover innovative low-carbon technologies, such as hydrogen and ammonia, while addressing synthesis, storage, and transportation hurdles. Its detailed content covers the flexibility of coupled gas and electricity networks, operational strategies for achieving net-zero carbon emissions, and intelligent methods for assessing network adaptability. Users will find a conceptual overview of decarbonization efforts for integrated energy systems and discussions on the feasibility of integrating artificial intelligence (AI) in these processes.
Further, the book discusses the decoupling of emissions from economic growth, the role of negative emission technologies (NETs), and the application of innovative energy solutions such as gas carbon capture and storage (CCS) and hydrogen production. Case studies illustrate successful implementations of integrated networks worldwide, highlighting challenges and key lessons learned. It not only highlights the urgent need for flexibility in these interconnected systems, particularly through demand-side management and energy storage systems, but also addresses the pressing challenges posed by climate change and the transition away from fossil fuels.
Further, the book discusses the decoupling of emissions from economic growth, the role of negative emission technologies (NETs), and the application of innovative energy solutions such as gas carbon capture and storage (CCS) and hydrogen production. Case studies illustrate successful implementations of integrated networks worldwide, highlighting challenges and key lessons learned. It not only highlights the urgent need for flexibility in these interconnected systems, particularly through demand-side management and energy storage systems, but also addresses the pressing challenges posed by climate change and the transition away from fossil fuels.
Puntos claves
Puntos claves
- Explores the flexibility mechanisms necessary for the effective integration of gas and electricity networks, focusing on demand response and energy storage solutions that enhance system resilience and grid optimization
- Examines operational and optimization strategies aimed at achieving net-zero carbon emissions within integrated gas and electricity networks
- Investigates the feasibility and application of artificial intelligence in the decarbonization of integrated energy networks
- Discusses the role of negative emission technologies (NETs) in contributing to low-carbon gas and electricity networks
- Presents real-world case studies of successful integrated gas and electricity networks, showcasing lessons learned and best practices
De interès para
De interès para
Researchers in clean energy, decarbonization specialists, hydrogen production experts, energy utility companies, energy economists, electrical engineers, mechanical engineers, artificial intelligence developers, policymakers, energy service providers, and students in energy systems
Índice
Índice
1. Flexibility for the coupled structure of integrated electricity and gas networks
2. Understanding flexibility in decarbonizing power systems: Needs, options, and future scenarios
3. System-of-Systems Approach to Peer-to-Peer Energy Trading in Integrated Energy Systems
4. Investigation and feasibility of artificial intelligence (AI) in decarbonization of integrated gas and electricity network
5. Sustainable Multi-Objective Operation of Microgrids: A Flexibility-Driven Approach for Electrical and Thermal Load Management
6. Advanced Data-Driven Control for Flexibility and Decarbonization in Integrated Power and Gas Networks
7. Role and value of compressor station in facilitating cost-effective energy system decarbonization: A case study
8. Applicability of negative emission technologies: Challenges and contributions in low-carbon gas and electricity networks
9. Hydrogen electrolyzers as a source of flexibility to power systems
10. Net zero energy supply, oxy turbine power cycles, gas carbon capture and hydrogen production technologies
11. Coordinated Load Shedding in Integrated Gas and Electricity Networks: Concept, Modeling, Challenges, and Future Directions
2. Understanding flexibility in decarbonizing power systems: Needs, options, and future scenarios
3. System-of-Systems Approach to Peer-to-Peer Energy Trading in Integrated Energy Systems
4. Investigation and feasibility of artificial intelligence (AI) in decarbonization of integrated gas and electricity network
5. Sustainable Multi-Objective Operation of Microgrids: A Flexibility-Driven Approach for Electrical and Thermal Load Management
6. Advanced Data-Driven Control for Flexibility and Decarbonization in Integrated Power and Gas Networks
7. Role and value of compressor station in facilitating cost-effective energy system decarbonization: A case study
8. Applicability of negative emission technologies: Challenges and contributions in low-carbon gas and electricity networks
9. Hydrogen electrolyzers as a source of flexibility to power systems
10. Net zero energy supply, oxy turbine power cycles, gas carbon capture and hydrogen production technologies
11. Coordinated Load Shedding in Integrated Gas and Electricity Networks: Concept, Modeling, Challenges, and Future Directions
Detalles del producto
Detalles del producto
- Edición: 1
- Última edición
- Publicado: 17 de junio de 2026
- Idioma: Inglés
Sobre los editores
Sobre los editores
MA
Mohammad Taghi Ameli
Mohammad Taghi Ameli received his B.Sc. degree in electrical engineering from Technical College of Osnabrück, Germany, in 1988, and his M.Sc. and Ph.D. degrees from Technical University of Berlin, Berlin, Germany, in 1992 and 1997, respectively. He is a Professor of Department of Electrical Engineering and Head of Electrical Networks Research Institute at Shahid Beheshti University. He was the General Director of the Iran Research and Technology Institute for Electric Machines for three years. His research interests include power system simulation, operation, planning, and control of power systems, renewable energy in power systems, and smart grids.
Afiliaciones y experiencia
Professor of Department of Electrical Engineering and Head of Electrical Networks Research Institute, Shahid Beheshti University, IranMA
Mohammad Mehdi Amiri
Mohammad Mehdi Amiri got his PhD degree in electrical engineering department at Shahid Beheshti University. His research is mainly focused on the integrated operation of gas/hydrogen and electricity networks, electricity markets, and decarbonization. He collaborates with the Electrical Networks Research Institute as a research associate and Noursun Energy Company as an optimization and electricity market manager.
Afiliaciones y experiencia
Research Associate, Electrical Networks Institute, Shahid Beheshti University, Iran; Optimization and Electricity Market Manager, Noursun Energy CompanyHA
Hossein Ameli
Hossein Ameli is an advanced research fellow in the Department of Electrical and Electronic Engineering at Imperial College London. He received his PhD from Imperial College London in 2018 and has more than 12 years of experience in integrated energy system modelling. His expertise spans the planning and operation of whole-energy systems, with particular emphasis on electricity, gas and hydrogen interactions, system flexibility,
resilience, and pathways to net zero. He has contributed to major research, policy and industry projects, including work for the UK Climate Change Committee (CCC) and the National Energy System Operator (NESO). He
is a contributing author to the IPCC Working Group III and a member of the UNECE Committee on Sustainable Energy
Afiliaciones y experiencia
Advanced Research Fellow, Department of Electrical and Electronic Engineering, Imperial College LondonSA
Sasan Azad
Sasan Azad is a research associate in the Electrical Network Research Institute at Shahid Beheshti University, Iran. His main areas of interest are the security and voltage stability of power systems, smart grids, and electric vehicles
Afiliaciones y experiencia
Research Associate, Electrical Networks Research Institute, Shahid Beheshti University, IranMD
Mohammadreza Daneshvar
Mohammadreza Daneshvar, PhD, SMIEEE, is an Assistant Professor, founder and head of the Laboratory of Multi-Carrier Energy Networks Modernization at the Faculty of Electrical and Computer Engineering, University of Tabriz, Tabriz, Iran. Prior to that, he was a postdoctoral research fellow in the field of modern multi-energy networks at the Smart Energy Systems Lab of the University of Tabriz for two years. He obtained his MSc and PhD degrees in Electrical Power Engineering from the University of Tabriz, all with honors. He has (co)authored more than 50 technical journal and conference articles, 10 books, 30 book chapters, and 10 national and international research projects in the field. Dr. Daneshvar is a member of the Editorial Board of the Energy and Built Environment Journal and the Early Career Editorial Board of the Sustainable Cities and Society Journal. He also served as the guest editor for the Sustainable Cities and Society, and Sustainable Energy Technologies and Assessments journals. Moreover, he serves as an active reviewer with more than 130 top journals, and was ranked among the top 1% of reviewers in Engineering and Cross-Field based on Publons global reviewer database. His research interests include Smart Grids, Transactive Energy, Energy Management, Renewable Energy Sources, Integrated Multi-Energy Systems, Grid Modernization, Electrical Energy Storage Systems, Sustainable Cities and Society, Microgrids, Energy Hubs, Machine Learning and Deep Learning, Digital Twin, and Optimization Techniques and AI.
Afiliaciones y experiencia
Assistant Professor, Laboratory of Multi-Carrier Energy Networks Modernization, Faculty of Electrical and Computer Engineering, University of Tabriz, IranMQ
Meysam Qadrdan
Meysam Qadrdan is a Professor of Energy Networks and Systems, and a RAEng Industrial Fellow in Cardiff University, UK. He conducts fundamental and applied research into the modelling and analysis of integrated energy systems (electricity, gas, hydrogen, heat). He collaborates with National Grid Gas, as his Industry Host for the RAEng Fellowship, to study the role of hydrogen in achieving net-zero in the Great Britain.
Afiliaciones y experiencia
Professor of Energy Networks and Systems, and a RAEng Industrial Fellow, Cardiff University, UKGS
Goran Strbac
Goran Strbac is a Professor of Energy Systems, with extensive experience in advanced modelling and analysis of operation, planning, security and economics of energy systems. He led the development of novel advanced analysis approaches and methodologies that have been extensively used to inform industry, governments and regulatory bodies about the role and value of emerging new technologies and systems in supporting cost effective evolution to smart low carbon energy future. He is currently Director of the joint Imperial-Tsinghua Research Centre on Intelligent Power and Energy Systems, Leading Author in IPCC WG 3, Member of OFGEM RIIO-2 Challenging Group, Member of the UK Smart System Forum, Member of the European Technology and Innovation Platform for Smart Networks for the Energy Transition, and Member of the Joint EU Programme in Energy Systems Integration of the European Energy Research Alliance.
Afiliaciones y experiencia
Professor and Chair in Electrical Energy Systems, Department of Electrical and Electronic Engineering, Imperial College London, United Kingdom