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OverviewLignin, a plant constituent, is the second most abundant biopolymer on earth. The biosphere is estimated to contain 3 x 1011 tonnes of lignin with an annual biosynthesis rate of approximately 2 x 1010 tonnes. In order to make paper products, wood in the form of whole logs, chips or sawmill residues first need to be reduced to discrete fibres/pulps by a chemical or mechanical pulping method. In chemical pulping of wood, fibres are produced in a yield of 45-55% through the dissolution of lignin by the pulping chemicals. The dissolved lignin, about 50 million tonnes per year, is used as a low-grade fuel for the chemical pulping process. There is a tremendous economics incentive to find better uses of such enormous amount of lignin. In mechanical pulping of wood, fibres are produced in a yield of 90-98% through the action of mechanical forces that separate the fibres but retain the lignin. The main use of high-yield, lignin-rich mechanical wood fibres has been confined to low-quality, non-permanent papers such as newsprint and telephone directories due to the light-induced photooxidation of lignin. Effective photostabilisation of lignin in mechanical wood fibres/pulps will enable their wider use in high-quality paper products. In Asia and other areas of the world where forest resources are less abundant, non-wood plant materials such as straw, bagasse and bamboo have been used to make paper products for many centuries. The effective isolation and the product development of lignin from chemical pulping of non-wood plant materials have become increasingly more important because the internal use of the lignin is technically complex and the traditional way of discharging the lignin-containing, pulping spent liquors to the environment is no longer acceptable. This volume covers the areas of chemical modification of lignin, from chemical pulping of wood and non-wood materials, the properties and usage of the modified lignin as components of polymer composites, and as fine chemicals, fertilizers, pulping catalysts, and so forth. It also describes the recent advances in chemical modification lignin aimed at photostabilization and upgrading of high-yield, lignin-rich mechanical wood pulps/papers. Full Product DetailsAuthor: Thomas Q. HuPublisher: Springer Science+Business Media Imprint: Kluwer Academic/Plenum Publishers Edition: 2002 ed. Dimensions: Width: 17.80cm , Height: 2.40cm , Length: 25.40cm Weight: 0.773kg ISBN: 9780306467691ISBN 10: 0306467690 Pages: 291 Publication Date: 31 March 2002 Audience: College/higher education , Professional and scholarly , Undergraduate , Postgraduate, Research & Scholarly Format: Hardback Publisher's Status: Active Availability: Out of stock  The supplier is temporarily out of stock of this item. It will be ordered for you on backorder and shipped when it becomes available. Table of Contents1. Starch-Lignin Films.- 2. Lignosulfonic Acid-Doped Polyaniline (Ligno-PaniTM) — A Versatile Conducting Polymer.- 3. Polyurethanes Containing Lignin.- 4. Lignins as Macromonomers for Polyesters and Polyurethanes.- 5. Lignin and Its Polyblends — A Review.- 6. Arboform® — A Thermoplastic, Processable Material from Lignin and Natural Fibers.- 7. Lignin-Based Carbon Fibers.- 8. The Use of Lignosulfonates as Water Reducing Agents in the Manufacture of Gypsum Wallboard.- 9. Modified Kraft Lignin and Its Use for Soil Preservation.- 10. Nitrogenous Fertilizers from Lignins - A Review.- 11. Pulping Catalysts from Lignin - the Diels — Alder Step.- 12. Acetylation of Lignin and Photostabilization of Lignin-Rich Mechanical Wood Pulp and Paper.- 13. Catalytic Modification and Photostabilization of Lignin Functional Groups.- 14. Characteristics, Industrial Sources, and Utilization of Lignins from Non-Wood Plants.ReviewsAuthor InformationTab Content 6Author Website:Countries AvailableAll regions |
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