Name: Advanced Membrane Science and Technology for Sustainable Energy and Environmental Applications By Angelo Basile (R&D Manager, ECO2Energy (Rome) and Hydrogenia (Genoa) and Department of Engineering, University Campus Bio-medical, Rome, Italy)
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Advanced Membrane Science and Technology for Sustainable Energy and Environmental Applications Summary

Advanced Membrane Science and Technology for Sustainable Energy and Environmental Applications by Angelo Basile (R&D Manager, ECO2Energy (Rome) and Hydrogenia (Genoa) and Department of Engineering, University Campus Bio-medical, Rome, Italy)

Membrane materials allow for the selective separation of gas and vapour and for ion transport. Materials research and development continues to drive improvements in the design, manufacture and integration of membrane technologies as critical components in both sustainable energy and clean industry applications. Membrane utilisation offers process simplification and intensification in industry, providing low-cost, and efficient and reliable operation, and contributing towards emissions reductions and energy security. Advanced membrane science and technology for sustainable energy and environmental applications presents a comprehensive review of membrane utilisation and integration within energy and environmental industries. Part one introduces the topic of membrane science and engineering, from the fundamentals of membrane processes and separation to membrane characterization and economic analysis. Part two focuses on membrane utilisation for carbon dioxide (CO2) capture in coal and gas power plants, including pre- and post-combustion and oxygen transport technologies. Part three reviews membranes for the petrochemical industry, with chapters covering hydrocarbon fuel, natural gas and synthesis gas processing, as well as advanced biofuels production. Part four covers membranes for alternative energy applications and energy storage, such as membrane technology for redox and lithium batteries, fuel cells and hydrogen production. Finally, part five discusses membranes utilisation in industrial and environmental applications, including microfiltration, ultrafiltration, and forward osmosis, as well as water, wastewater and nuclear power applications. With its distinguished editors and team of expert contributors, Advanced membrane science and technology for sustainable energy and environmental applications is an essential reference for membrane and materials engineers and manufacturers, as well as researchers and academics interested in this field.

About Angelo Basile (R&D Manager, ECO2Energy (Rome) and Hydrogenia (Genoa) and Department of Engineering, University Campus Bio-medical, Rome, Italy)

Angelo Basile, a chemical engineer, is the author of hundreds of papers, books, chapter books, and special issues, with also various Italian, European, and worldwide patents. Basile is an associate editor of various international journals (IJHE, APCEJ, etc.), editor-in-chief of the International Journal of Membrane Science and Technology, and a member of the editorial board of more than 25 international journals. Today Basile is an R&D manager at both ECO2Energy (Rome) and Hydrogenia (Genoa) and is collaborating with the Department of Engineering at the University Campus Bio-medical of Rome (Italy). Dr Suzana Pereira Nunes is Principal Research Scientist at the Centre for Advanced Membranes and Porous Materials, King Abdullah University of Science and Technology, Kingdom of Saudi Arabia. The editors are renowned for their research and development of advanced membrane technologies.

Contributor contact details Woodhead Publishing Series in Energy Preface Part I: Introduction to membrane science and engineering Chapter 1: Fundamental membrane processes, science and engineering Abstract: 1.1 Introduction 1.2 Membrane processes 1.3 Conclusions and future trends Chapter 2: Fundamental science of gas and vapour separation in polymeric membranes Abstract: 2.1 Introduction 2.2 Basic principles and definitions of separation processes 2.3 Effects of the properties of penetrants and polymers 2.4 Effects of pressure on transport parameters 2.5 Effects of temperature on transport parameters 2.6 Gas permeability of polymers: objects of membrane gas separation 2.8 Appendix: list of symbols Chapter 3: Characterization of membranes for energy and environmental applications Abstract: 3.1 Polymer and carbon molecular sieve membranes 3.2 Zeolite and mixed matrix membranes 3.3 Mass transport characterization 3.4 Conclusions 3.6 Appendix: list of symbols Chapter 4: Economic analysis of membrane use in industrial applications Abstract: 4.1 Introduction 4.2 Economic analysis 4.3 Case studies 4.4 Conclusions and future trends Part II: Membranes for coal and gas power plants: carbon dioxide (CO2) capture, synthesis gas processing and oxygen (O2) transport Chapter 5: Membrane technology for carbon dioxide (CO2) capture in power plants Abstract: 5.1 Introduction 5.2 Reasons for using membranes for carbon dioxide (CO2) separation and sequestration 5.3 A short review of membrane technology for CO2 separation 5.4 Performance of membrane processes for CO2 sequestration 5.5 Membrane modules for CO2 sequestration 5.6 Design for power plant integration 5.7 Cost considerations and membrane technology at the industrial scale 5.8 Modelling aspects of gas permeation membrane modules 5.9 Conclusions and future trends 5.11 Appendix: list of symbols Chapter 6: Polymeric membranes for post-combustion carbon dioxide (CO2) capture Abstract: 6.1 Introduction 6.2 Basic principles of flue gas membrane separation 6.3 Membrane development and applications in power plants 6.4 Operation and performance issues and analysis 6.5 Advantages and limitations 6.6 Future trends Chapter 7: Inorganic membranes for pre-combustion carbon dioxide (CO2) capture Abstract: 7.1 Introduction 7.2 Inorganic membranes for carbon dioxide (CO2) separation 7.3 Membrane reactors for CO2 capture 7.4 Techno-economic analysis of the integrated gasification combined cycle (IGCC) and natural gas combined cycle (NGCC) 7.5 Conclusions and future trends Chapter 8: Inorganic membranes for synthesis gas processing Abstract: 8.1 Introduction 8.2 Basic principles of membrane operation 8.3 Membrane materials and development 8.4 Application and integration in industry 8.5 Membrane modules 8.6 Future trends 8.7 Conclusions 8.9 Appendix: list of symbols Chapter 9: Oxygen transport membranes: dense ceramic membranes for power plant applications Abstract: 9.1 Introduction 9.2 Oxygen transport membrane materials, development and design 9.3 Principles of oxygen membrane separation 9.4 Application and integration in power plants 9.5 Oxygen transport membranes 9.6 Future trends 9.7 Conclusions 9.8 Acknowledgements Part III: Membranes for the petrochemical industry: hydrocarbon fuel and natural gas processing, and advanced biofuels production Chapter 10: Membranes for hydrocarbon fuel processing and separation Abstract: 10.1 Introduction 10.2 Membrane materials, development and design for hydrocarbon processing 10.3 Separation of olefins and paraffins 10.4 Removal of hydrocarbons from liquid streams 10.5 Nanotechnologies from fundamental research to large-scale industry 10.7 Appendix: list of symbols Chapter 11: Polymeric membranes for natural gas processing Abstract: 11.1 Introduction 11.2 Polymeric membrane operations in natural gas processing 11.3 Membrane materials, development and design for natural gas processing 11.4 Operation and performance issues and analysis 11.5 Application and integration into natural gas operations 11.6 Advantages and limitations 11.7 Future trends 11.10 Appendix: list of symbols Chapter 12: Membranes for advanced biofuels production Abstract: 12.1 General overview of second-generation biofuels 12.2 Hydrolysis of biomass to produce sugars 12.3 Key role of process engineering for second-generation biofuels production 12.4 Membrane bioreactors 12.5 Biocatalyst continuously separated by a membrane system and recirculated into the reaction tank 12.6 Biocatalyst immobilized onto the membrane surface 12.7 Continuous stirred tank reactor with biocatalyst immobilized on the membrane surface (CSTMB) 12.8 Single pass membrane bioreactor 12.9 Hollow fibre membrane bioreactor with recycling of unreacted substrate 12.10 Conclusions 12.13 Appendix: list of symbols Part IV: Membranes for alternative energy applications: batteries, fuel cells and hydrogen (H2) production Chapter 13: Ion exchange membranes for vanadium redox flow batteries Abstract: 13.1 Electrochemical energy storage 13.2 Vanadium redox flow batteries 13.3 Membranes 13.4 Conclusions Chapter 14: Membranes for lithium batteries Abstract: 14.1 Introduction 14.2 Types of lithium battery and basic operating principles 14.3 Polymer electrolyte membranes for advanced lithium batteries 14.4 Conclusions and future trends Chapter 15: Proton exchange membranes for fuel cells Abstract: 15.1 Introduction 15.2 Basic operating principles and types of fuel cell 15.3 Membrane materials, design and fabrication processes 15.4 Membrane performance in operation: issues and analysis 15.5 Integration and application of proton exchange membrane (PEM) fuel cell systems 15.6 Advantages and limitations of PEM fuel cells 15.7 Future trends 15.10 Appendix: list of symbols Chapter 16: Functional ceramic hollow fibre membranes for catalytic membrane reactors and solid oxide fuel cells Abstract: 16.1 Introduction 16.2 Membrane materials issues 16.3 Membrane development routes and macrostructure control 16.4 A multifunctional dual-layer hollow fibre membrane reactor (DL-HFMR) for methane conversion 16.5 Dual-layer hollow fibres for a micro-tubular solid oxide fuel cell (SOFC) 16.6 Other ways of improving ceramic dual-layer hollow fibres 16.7 Conclusions Chapter 17: Proton-conducting ceramic membranes for solid oxide fuel cells and hydrogen (H2) processing Abstract: 17.1 Introduction 17.2 Operation principle of proton-conducting ceramic membranes and demands on materials 17.3 Protons and proton conductance in ceramics 17.4 Conductivity and hydrogen (H2) flux of selected classes of ceramic membrane materials 17.5 Structure of selected classes of proton-conducting materials 17.6 Chemical stability of selected classes of ceramic membrane materials 17.7 Conclusions 17.8 Acknowledgements Chapter 18: Membrane electrolysers for hydrogen (H2) production Abstract: 18.1 Introduction 18.2 Basic principles of electrolysis 18.3 Membrane materials 18.4 Membrane performance 18.5 Application and integration of electrolyser systems 18.6 Some advantages and limitations of current membrane materials 18.7 Future trends 18.10 Appendix: nomenclature Chapter 19: Biomimetic membrane reactors for hydrogen (H2) production Abstract: 19.1 Introduction 19.2 General background to the concept 19.3 An ambitious goal with numerous challenges 19.4 Thermodynamic limitations and device design 19.5 Integrated engineering approach for solar-to-fuel conversion 19.6 Conclusions Part V: Membranes for industrial, environmental and nuclear applications Chapter 20: Membranes for industrial microfiltration and ultrafiltration Abstract: 20.1 Introduction 20.2 Basic principles of microfiltration and ultrafiltration 20.3 Membrane materials and membrane preparation technology 20.4 Module configuration and process design 20.5 Concentration polarization and membrane fouling 20.6 Applications 20.7 Microfiltration and ultrafiltration in integrated processes 20.8 Advantages and limitations 20.9 Future trends Chapter 21: Membranes for forward osmosis in industrial applications Abstract: 21.1 Introduction 21.2 Mechanism of forward osmosis 21.3 Membranes for forward osmosis 21.4 Forward osmosis membrane modules 21.5 Effect of various parameters on transmembrane flux 21.6 Applications of forward osmosis 21.7 Conclusions 21.8 Acknowledgements Chapter 22: Degradation of polymeric membranes in water and wastewater treatment Abstract: 22.1 Introduction 22.2 Polymer materials and module design 22.3 Membrane failure and operational issues 22.4 Membrane degradation mechanisms 22.5 Identification and monitoring of membrane degradation 22.6 Materials degradation control strategies 22.7 Future trends 22.9 Acknowledgements Chapter 23: Membranes for photocatalysis in water and wastewater treatment Abstract: 23.1 Introduction 23.2 Basic principles of heterogeneous photocatalysis 23.3 Membrane materials developments and design for photocatalysis 23.4 Membrane operations performance issues and analysis: case studies 23.5 Future trends Chapter 24: Membranes for nuclear power applications Abstract: 24.1 Introduction 24.2 Membranes for nuclear fission applications 24.3 Membranes for nuclear fusion applications 24.4 Conclusions 24.5 Future trends Index

Additional information

Sku

NLS9780081016909

ISBN 13

9780081016909

ISBN 10

0081016905

Title

Advanced Membrane Science and Technology for Sustainable Energy and Environmental Applications by Angelo Basile (R&D Manager, ECO2Energy (Rome) and Hydrogenia (Genoa) and Department of Engineering, University Campus Bio-medical, Rome, Italy)

Author

Angelo Basile (R&D Manager, ECO2Energy (Rome) and Hydrogenia (Genoa) and Department of Engineering, University Campus Bio-medical, Rome, Italy)

Series

Woodhead Publishing Series in Energy

Condition

New

Binding type

Paperback

Publisher

Elsevier Science & Technology

Year published

2016-08-19

Number of pages

848

Prizes

N/A

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Advanced Membrane Science and Technology for Sustainable Energy and Environmental Applications Angelo Basile (R&D Manager, ECO2Energy (Rome) and Hydrogenia (Genoa) and Department of Engineering, University Campus Bio-medical, Rome, Italy)

Advanced Membrane Science and Technology for Sustainable Energy and Environmental Applications by Angelo Basile (R&D Manager, ECO2Energy (Rome) and Hydrogenia (Genoa) and Department of Engineering, University Campus Bio-medical, Rome, Italy)

Advanced Membrane Science and Technology for Sustainable Energy and Environmental Applications Summary

Advanced Membrane Science and Technology for Sustainable Energy and Environmental Applications by Angelo Basile (R&D Manager, ECO2Energy (Rome) and Hydrogenia (Genoa) and Department of Engineering, University Campus Bio-medical, Rome, Italy)

About Angelo Basile (R&D Manager, ECO2Energy (Rome) and Hydrogenia (Genoa) and Department of Engineering, University Campus Bio-medical, Rome, Italy)

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