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Front Cover; Green and Sustainable Manufacturing of Advanced Materials; Copyright; Contents; Contributors; Preface; Part I: Material Conservation, Recovery, Recycling and Reuse ; Chapter 1: Green and Sustainable Manufacturing of Advanced Materials-Progress and Prospects; 1. Introduction; 2. Focus Areas; 2.1 Material Conservation, Recovery, and Recycling; 2.2 Sustainable Manufacturing-Metallic Materials; 2.3 Sustainable Manufacturing-Ceramic Materials; 2.4 Sustainable Manufacturing-Polymeric and Composite Materials
Chapter 2: Moving Beyond Single Attributes to Holistically Assess the Sustainability of Materials1. Evolution of Views of Environmentally Preferable Materials and Products; 2. Examination of Specific Single Environmental Attributes; 2.1 Recycled Content; 2.2 Recyclability; 2.3 Bio-Based Materials; 3. The Use of Life-Cycle Analysis to Evaluate Multiple Product Attributes; 3.1 The Development of LCA as a Methodology; 3.2 Use of Life-Cycle Assessment to Quantify and Reduce Environmental Impacts; 3.3 The Use of Life-Cycle Analyses to Compare Products or Materials
3.4 Requirements for Using Life-Cycle Assessments and Environmental Product Declarations4. Design for the Environment; 5. Continual Evolution; 6. Conclusions; Acknowledgments; References; Chapter 3: Eco-Materials and Life-Cycle Assessment; 1. Eco-Materials; 1.1 Introduction to Eco-Materials; 1.2 Development of Eco-Materials Concept; 1.3 Research and Development of Eco-Materials and Related Technology in China; 2. Introduction of Life-Cycle Assessment; 2.1 Sustainability and Life-Cycle Thinking; 2.2 Definition of Life-Cycle Assessment; 2.3 Framework of Life-Cycle Assessment
2.4 Development and Application of Life-Cycle Assessment2.5 Database and Analysis Tool of LCA; 3. Development of LCIA Methodology in China; 3.1 LCIA Model of Abiotic Resource Depletion in China; 3.2 LCIA Model of Land Use in China [24]; 3.3 Methodology of LCIA Needs to Be Improved Continuously; 4. LCA Practice on Materials Industry in China; 4.1 Case Study: LCA of Iron and Steel Production in China; 4.2 Case Study: LCA of Magnesium Production in China [28]; 4.3 Case Study: Greenhouse Gas Analysis of Chinese Aluminum Production Based on LCA [29]
4.4 Case Study: Layout Adjustment of Cement Industry in Beijing Based on LCA [30]4.5 Case Study: LCA of Flat Glass Production in China [31]; 4.6 Case Study: CO 2 Emission Analysis of Calcium Carbide Sludge Clinker [32]; 4.7 Case Study: LCA in Chinese Energy Sector; 4.8 Case Study: LCA of Civilian Buildings in Beijing [35]; 5. Conclusions; References; Chapter 4: Exergetic Aspects of Green Ceramic Processing; 1. Introduction; 2. Illustrative Example for Understanding Exergy and Heat Energy [1-3]
2.1 Exergy Analysis 1: Entropy Increase due to Mixture and Exergy Calculation of N 2 and O 2 Gas
Sustainable development is a globally recognized mandate and it includes green or environment-friendly manufacturing practices. Such practices orchestrate with the self-healing and self-replenishing capability of natural ecosystems. Green manufacturing encompasses synthesis, processing, fabrication, and process optimization, but also testing, performance evaluation and reliability. The book shall serve as a comprehensive and authoritative resource on sustainable manufacturing of ceramics, metals and their composites. It is designed to capture the diversity and unity of methods and approaches
Description based on online resource; title from PDF title page (ebrary, viewed September 3, 2015).