Biodegrable polymers and plastics
Author(s)
Bibliographic Information
Biodegrable polymers and plastics
Kluwer Academic/Plenum Publishers, c2003
Available at 6 libraries
  Aomori
  Iwate
  Miyagi
  Akita
  Yamagata
  Fukushima
  Ibaraki
  Tochigi
  Gunma
  Saitama
  Chiba
  Tokyo
  Kanagawa
  Niigata
  Toyama
  Ishikawa
  Fukui
  Yamanashi
  Nagano
  Gifu
  Shizuoka
  Aichi
  Mie
  Shiga
  Kyoto
  Osaka
  Hyogo
  Nara
  Wakayama
  Tottori
  Shimane
  Okayama
  Hiroshima
  Yamaguchi
  Tokushima
  Kagawa
  Ehime
  Kochi
  Fukuoka
  Saga
  Nagasaki
  Kumamoto
  Oita
  Miyazaki
  Kagoshima
  Okinawa
  Korea
  China
  Thailand
  United Kingdom
  Germany
  Switzerland
  France
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  United States of America
Note
Includes bibliographical references and index
Description and Table of Contents
Description
Synthetic and semi-synthetic polymeric materials were originally developed for their durability and resistance to all forms of degradation including biodegradation. Such materials are currently widely accepted because of their ease of processability and amenability to provide a large variety of cost effective items that help to enhance the comfort and quality of life in the modern industrial society. However, this widespread utilization of plastics has contributed to a serious plastic waste burden, and the expectation for the 21st century is for an increased demand for polymeric material. This volume focuses on a more rational utilization of resources in the fabrication, consumption and disposal of plastic items, specifically: -Environmentally Degradable Polymeric Materials (EDPs); -Water-soluble/Swellable Biodegradable Polymers; -EDPs from Renewable Resources; -Biopolymers; -Bioresorbable Materials for Biomedical Applications; -Biorelated Polymers; -Standards and Regulations on EDPs.
Table of Contents
- Part 1: Standards and Policies: 1: Science and Standards
- G. Scott. 1. Why Are Standards Necessary. 2. Life Cycle Assessment of Biodegradable Polymers. 3. Degradation of Carbon-Chain Polymers. 4. Hydroperoxides and the Peroxidation Chain Mechanism. 5. Microbial Degradation of Carbon-Chain Polymers. 6. Characterisation of Biodegradable Polymers. 7. Applications of Degradable Plastics in Agriculture and Horticulture. 8. Applications of Degradable Plastics in Waste Management. 9. Oxo-Biodegradable Polymers in the Soil. 10. Science-Based Standards for Degradable Polymers. 11. Conclusions. 2. Biodegradability And Compostability
- F. Degli Innocenti. 1. Everything is Biodegradable. Can Everything be Bio-Recycled. 2. Role of Standardization. 3. Compostability of Packaging: the EN 13432. 4. Other Notable Standards on Compostability. 5. Other Notable Standards on Compostability. 6. New Frontiers in Standardisation. 3: Study of The Aerobic Biodegradability of Plastic Materials Under Controlled Compost
- A. Hoshino, M. Tsuji, M. Ito, M. Momochi, A. Mizutani, K. Takakuwa, S. Higo, H. Sawada, S. Uematsu. 1. Introduction. 2. Materials and Methods. 3. Results and Discussion. 4. Conclusions. 4: Environmentally Degradable Plastics And ICS-UNIDO Global Program
- S. Miertus, Xin Ren. 1. Introduction. 2. EDPS and Waste Management. 3. EDPS and Renewable Resources. 4. Life Cycle Consideration. 5. Situation and Needs in Developing Countries. 6. ICS-UNIDO Activities on EDPS. 7. Conclusions. 5: Biodegradable Plastics: Views of APME (Association of Plastics Manufacturers in Europe)
- F. Marechal. 1. Introduction. 2. APME Position. 3. Background. 4. Conclusions. 6: Market Introduction of Compostable Packaging: Consumers' Acceptance and Disposal Habits in the Kassel Project
- J. Reske. 1. Introduction. 2. Background: The Situation before the Kassel Project. 3. The Project: Issues and Participants. 4. Results. Part 2: Biobased Systems:- 7: Do Biopolymers Fulfill Our Expectations Concerning Environmental Benefits
- M. Patel. 1. Biopolymers - A Relevant Topic? 2. Environmental Superiority? - Having a Closer Look at Starch Polymers. 3. Environmental Comparison - A Bird's View. 4. Are We Critical Enough? 5. What Can We Conclude? 8: Biobased Polymeric Materials
- H. Hatakeyama, Y. Asano, T. Hatakeyam. 1. Introduction. 2. Methods of Characterisation. 3. Saccharide- and Lignin-Based PU Derivatives. 4. Saccharide and Lignin-Based PCL Derivatives. 5. Polyurethanes from Saccharide and Lignin Based PCLs. 6. Conclusions. 9: Biodegradable Kraft Lignin-Based Thermoplastics
- Yan Li, S. Sarkanen. 1. Introduction. 2. Towards the first Thermoplastics with High Lignin.
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