Bioenergy Systems for the Future: Prospects for Biofuels and Biohydrogen examines the current advances in biomass conversion technologies for biofuels and biohydrogen production, including their advantages and challenges for real-world application and industrial-scale implementation.
In its first part, the book explores the use of lignocellulosic biomass and agricultural wastes as feedstock, also addressing biomass conversion into biofuels, such as bioethanol, biodiesel, bio-methane, and bio-gasoline. The chapters in Part II cover several different pathways for hydrogen production, from biomass, including bioethanol and bio-methane reforming and syngas conversion. They also include a comparison between the most recent conversion technologies and conventional approaches for hydrogen production.
Part III presents the status of advanced bioenergy technologies, such as applications of nanotechnology and the use of bio-alcohol in low-temperature fuel cells. The role of advanced bioenergy in a future bioeconomy and the integration of these technologies into existing systems are also discussed, providing a comprehensive, application-oriented overview that is ideal for engineering professionals, researchers, and graduate students involved in bioenergy.
- Explores the most recent technologies for advanced liquid and gaseous biofuels production, along with their advantages and challenges
- Presents real-life application of conversion technologies and their integration in existing systems
- Includes the most promising pathways for sustainable hydrogen production for energy applications
Please Note: This is an On Demand product, delivery may take up to 11 working days after payment has been received.
Biomass to bioenergy 1. Biomass pretreatment and transformation from agricultural wastes 2. Efficient transformation of non-food agricultural lignocelluloses 3. Production of bio-alcohol and bio-methane 4. Light olefins/biogasoline production from biomass5. Bioenergy from stillage anaerobic digestion to enhance the energy balance ratio of ethanol production
Hydrogen production 6. Thermodynamic analysis of ethanol reforming for hydrogen production7. Catalysts for conversion of synthesis gas8. Distributed H2 production from bio-alcohols and bio-methane in conventional steam reforming units9. H2 production from bio-alchools and bio-methane steam reforming in conventional and membrane reactors 10. Formation of hydrogen rich gas via conversion of lignocellulosic biomass and its decomposition products 11. Advantages and diadvantages of recent biomass conversion technologies compared to conventional approaches for hydrogen production
Bioenergy technology aspects/status 12. Nanocomposites for ''Nano Green Energy'' Applications 13. Integration of membrane technologies into conventional existing systems in the food industry 14. Integration of microalgae into an existing biofuel industry 15. Low-temperature fuel cell operated with bio-alcohol fuels 16. Syngas cleaning system for power generation 17. Bioenergy production from second and third generation feedstocks
Francesco Dalena, degree in Chemistry with Ph.D. on "Translational medicine at the Chemistry Department of the University of Calabria (Italy), is expert in "Chemistry of advanced materials". His research field ranges from the bioenergy sector to inorganic membrane reactors, to chemical kinetics and to the chemistry of artistic masterpiece. He is editor of various books, such as: "Hydrogen Production, Separation and Purification for Energy", 2016, IET Pub.; "Alcohol and bioalcohol: characteristic, proprieties and use", 2014, Nova Pub., "Methanol: Science and Engineering, Elsevier Pub.
Angelo Basile, a Chemical Engineer, is a senior Researcher at the ITM-CNR where he is responsible for research related to both the ultra-pure hydrogen production and CO2 capture using Pd-based Membrane Reactors. He also holds a full professor of Chemical Engineering Processes. He has 140 scientific papers in peer to peer journals and 230 papers in international congresses; editor/author of more than 40 scientific books and 100 chapters on international books on membrane science and technology; 6 Italian patents, 2 European patents and 5 worldwide patents. He is referee of 116 international scientific journals and member of the Editorial Board for 22 of them. Professor Basile is also associate editor of the international journal Hydrogen Energy and of the Asia-Pacific journal Chemical Engineering, and is Editor-in-chief of the international journal Membrane Science & Technology and Editor-in-chief of Membrane Processes (Applications), a section of the international journal Membranes. Professor Basile also prepared 25 special issues on membrane science and technology for many international journals (IJHE, Chem Eng. J., Cat. Today, etc.). He participated to and was/is responsible for many national and international projects on membrane reactors and membrane science, and previously served as Director of the ITM-CNR.
Claudio Rossi is full professor of Physical Chemistry at the Department of Biotechnology, Chemistry and Pharmacy of the University of Siena, coordinator of the NMR spectroscopy activity and responsible for the University of Siena of the research in the Agrifood sector. He has authored more than 200 scientific publications in qualified international journals and co-authored 2 Italian patents. Referee of numerous scientific journals in the field of Pure and Applied Chemistry. Claudio Rossi was the coordinator of six European projects funded by EU. He was the Director of the Department of Chemical and Biosystem Sciences of the University of Siena in the period 2002-2008. He was tutor of numerous students during the preparation of their PhD thesis and Master.