Lignocellulose for Future Bioeconomy
Coordonnateurs : Ariffin Hidayah, Sapuan S. M., Hassan Mohd Ali
Lignocellulose for Future Bioeconomy discusses the conversion and utilization of lignocellulosic biomass. This book focuses on the utilization of lignocelluloses for various products, including biopolymers, bionanomaterials and bioproducts. Recent findings in scientific investigation, engineering, product development, economic and lifecycle analysis are discussed, as are current synthesis technologies and potential applications. The book progresses from a discussion of the potential sources of biomass, to the refinement and processing of materials. A sampling of various sustainability issues faced by industries in their production methods and a look at real world examples of the use of lignocellulose-based materials in the bioeconomy round out the discussion.
1. Potential Tropical Species for Bioenergy2. Superheated Steam Pretreatment for Surface Modification of Lignocellulosic Materials3. Lignocellulose structure and the effect on bioproducts4. Multi-step pretreatment for cellulose separation5. Fermentable sugars from oil palm biomass: potential, issues and challenges6. Lignocellulose based fibres and their composites: preparation, properties and applications7. Cellulose Nanofiber Production from Oil Palm Biomass8. One-pot nanofibrillation and nanocomposites production through extrusion9. Tannin-based Bioresin as Adhesive10. Oligosaccharides from Hemicellulose11. Lignin-based adhesives and coatings12. Effect of stacking sequence of kenaf/glass fiber bands on filament winding hybrid energy absorption composite tubes13. Natural fibre reinforced biopolymer composites: Review14. Sustainability of oil palm biomass-based products15. R&D and Industrialization of Cellulose Nanofibers in Japan16. Biopolymer innovations and product development for packaging applications17. Oil Palm Biomass Biorefinery for Future Bioeconomy in Malaysia18. The Finnish way of the future bioeconomy19. Bioresources and biocommodities for the global bioeconomy20. Lignocellulose in Malaysian Bio Economy: The review of Bio Economy Transformation Program (BTP) 21. Design and fabrication of shoe shelf from kenaf fibre reinforced unsaturated polytester composites
S.M. Sapuan is an ‘A’ grade Professor of Composite Materials in the Department of Mechanical and Manufacturing Engineering, at the Universiti Putra Malaysia. He is also Head of the Advanced Engineering Materials and Composite Research Centre (AEMC) at UPM. He attained his BEng in Mechanical Engineering from the University of Newcastle, in Australia, and then went on to receive his MSc in Engineering Design, and PhD in Materials Engineering, from De Montfort University in the UK. He is a Professional Engineer, and a fellow of many professional societies including the Society of Automotive Engineers; The Academy of Science Malaysia; the International Society for Development and Sustainability; the Plastic and Rubber Institute Malaysia (PRIM); the Malaysian Scientific Association and the Institute of Materials Malaysia. He is an Honorary Member and past Vice President of the Asian Polymer Association and Founding Chairman and Honorary Member of The Society of Sugar Palm Development and Industry, Malaysia. During the course of his career, he has produced over 2000 publications including 880 journal papers, 55 books, and 180 book chapters..
M.A. Hassan is a Pr
- Presents information on lignocellulosic biomass management and its utilization for the production of bioproducts, biopolymers and bionanomaterials
- Highlights the applications of advanced materials developed from lignocellulosic biomass and their contribution towards future bioeconomy
- Discusses the lifecycle of lignocellulosic biomass
Date de parution : 04-2019
Ouvrage de 360 p.
15x22.8 cm
Thème de Lignocellulose for Future Bioeconomy :
Mots-clés :
Acid hydrolysis; Agricultural waste; Biobased products; Biocokes; Biocommodities; Bioeconomy; Bioeconomy transformation program; Bioenergy; Biofuels; Biomass; Biomass residues; Bionanocomposites; Biorefinery; Bioresources; Carbon dioxide assist; Cellulose; Cellulose isolation; Cellulose nanofiber; Cellulose nanofibril; Cellulose nanomaterial; Characterization; Coatings; Composites; Conceptual design; Depolymerizing; Epoxide resin; Eucalyptus; Extruder; Hydrothermal; Integrated biorefinery; Kenaf; Kenaf fiber; Kraft lignin; Lignin; Lignocellulose; Lignocellulose fibers; Lignocellulosic biomass; Logistic centers; Mangium; Mangrove; Nanocellulose; Nanocomposite; Nanocrystals; Nanofibrillation; Nanofibrils; Napier grass; Noncellulosic material; Nonchlorinated treatment; Oil palm biobased products; Oil palm biomass; Oil palm fronds; One-pot process; Palm oil industry; Phenolic resin; Plywood; Polymer; Polymer composites; Pretreatment; Reactive processing; Renewable energy; Roundtable on Sustainable Palm Oil (RSPO); Screw configuration; Screw element; Shoe shelf; Steam explosion; Sustainability; Tannin; Torrefaction; Trade; Tropical biomass; Tropical forest; Unsaturated polyester; Wood; Xylooligosaccharides; Zero emission system
