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内容概要

Hee-Gweon Woo is a professor at the Department of Chemistry, Chonnam National University, the Republic of Korea. Hong Li is a professor at the Institute of Polymer Chemistry, Nankai University, China.

书籍目录

1  Polyimides and High Performance Organic Polymers  1.1  Introduction  1.2  Aromatic Polyimides    1.2.1  Polyimides    1.2.2  Classification    1.2.3  Aromatic Polyimides    1.2.4  Synthesis of Aromatic Polyimides    1.2.5  Properties of Aromatic Polyimides    1.2.6  Applications for Aromatic Polyimides  1.3  Aliphatic Polyimides    1.3.1  Monomers for Fully Aliphatic Polyimides    1.3.2  Synthesis of Fully Aliphatic Polyimides    1.3.3  Structural Confirmation of Fully Aliphatic Polyimides    1.3.4  Properties of Fully Aliphatic Polyimides  1.4  Polyimides for Organic Light-Emitting Devices and Flexible Substrates    1.4.1  Semi-conducting Polyimides    1.4.2  Polyimides as Plastic Substrate for the Flexible OLED  1.5  Polyimide-Based Nanohybrids  1.6  Other General High Performance Polymers    1.6.1  Polyetheretherketon (PEEK)    1.6.2  Polysulphone (PSU)    1.6.3  Polysulfides    1.6.4  Polycarbonates (PC)    1.6.5  Polyamides (PA)    1.6.6  Poly(Butylene Terephthalate) (PBT)    1.6.7  Poly(Phenylene Oxides)    1.6.8  Polynorbornene (PNB)  1.7  Summary  References2  Advanced Biodegradable Organic Polymers  2.1  Introduction  2.2  Synthesis of Biodegradable Polymers by Polycondensation    2.2.1  General Polycondensation Technique    2.2.2  Post Polycondensation Technique    2.2.3  Chain-Extension Technique    2.2.4  Enzyme-Catalyzed Polycondensation  2.3  Synthesis of Biodegradable Polymers by Ring-Opening Polymerization    2.3.1  Monomers    2.3.2  Polymerization with Metal Catalysts    2.3.3  Polymerization Using Metal-Free Organic Catalysts    2.3.4  Enzyme-Catalyzed Ring-Opening Polymerization  2.4  Concluding Remarks  References3  High Functional Inorganic Polymers Containing Main Group 13 - 16 Elements in the Polymer Backbone Chain  3.1  Introduction  3.2  Group 14 Inorganic Polymers: Polysilanes, Polygermanes, Polystannanes, and their Copolymers    3.2.1  Dehydrocatenation of Group 14 Hydrides to Polymers    3.2.2  Redistributive Catenation of Group 14 Hydrides to Polymers.    3.2.3  Exhaustive Hydrosilylation, Hydrogermylation and Hydrostannylation of Group 14 Hydrides on Vinyl Derivatives.    3.2.4  Formation of Polysilane-Metal Nanoparticle Composites  3.3  Group 13 Inorganic Polymers: Polyborazines  3.4  Group 15 Inorganic Polymers: Polyphosphazenes  3.5  Group 16 Inorganic Polymers: Polysulfur and Poly(sulfur nitride)  3.6  Summary  References4  Preparation and Applications of Ceramic Composite Phases from Inorganic Polymers  4.1  Introduction  4.2  Preparation of Composite Phases from Inorganic Polymers    4.2.1  Si-C-B-N Ceramics via Hydroboration from Borazine Derivatives and Trivinylcyclotrisilazane    4.2.2  SiC/MoSi2 Ceramic Composites Prepared by Polymer Pyrolysis    2.2.3  Ti-B-N Composite from a Hybrid Precursor of Polybomzine' and Till2    4.2.4  A1-B-N Nanocomposite from Polyborazine and A1 Metal..    4.2.5  A1-Cr-Phosphates as Low Temperature Curable Binders..  4.3  Applications of Preceramic Polymers    4.3.1  Preparation of Carbon Fiber Reinforced BN Matrix Composite..    4.3.2  BN Film by Spin-Coating Process of a Polymeric Precursor..    4.3.3  Fabrication of SiC-Based Ceramic Microstructures  4.4  Summary  References  5  Chemical and Biological Sensors Based on Porous Silicon  Nanomaterials  5.1  Introduction  5.2  Interferometric Sensors Based on Porous Silicon Nanomaterials    5.2.1  Fabrication of Porous Silicon    5.2.2  Chemical Sensing Application of Porous Silicon    5.2.3  Biological Sensing Application of Porous Silicon  5.3  Summary  References6  Microbial Fuel Cells as the Real Source of Sustainable Energy  6.1  Introduction  6.2  Configurations and Designs of Microbial Fuel Cells    6.2.1  MFC Components    6.2.2  Two-Chambered MFCs    6.2.3  Single-Chambered MFCs    6.2.4  Up-Flow Mode MFCs    6.2.5  Stacked MFCs  6.3  Electrode Materials and Catalysts    6.3.1  Electrode Materials    6.3.2  Cathodic Catalysts  6.4  Performance of Microbial Fuel Cells    6.4.1  Parameters Defining the Performance of MFCs    6.4.2  Effects of Conditions When Operating MFCs  6.5  Metabolism in Microbial Fuel Cells  6.6  Applications  6.7  SummaryReferencesIndex

编辑推荐

There are great interests in six advanced technologies: nano-technology, bio-based technology, sensor technology, energy-based technology, high performance material-based technology, and fuel cell technology. During the past decades major progress in the synthesis, characterization, and applications of functional polymers has been accomplished along with the recent development of nano-bioscience and environment technology. This monograph titled Advanced Functional Materials contains six chapters spanning from polymers to ceramics, sensor, and to fuel cell: high performance organic polymers, biodegradable organic polymers,inorganic polymers, ceramic composite formation, sensor, and fuel cell.

作者简介

With recent developments in the polymer, ceramic, sensor, and 

fuel cell technology, a range of novel materials have been 

manufactured for advanced, compact, and electronic industry. 

Polymers, silicon, energy materials have received much attention 

in recent years. Advanced Func-tional Materials gives the most 

recent research results on polymer, fine ceramics, sensor, and 

green fuel cells. The content of this book, mainly based on the 

authors' recent research results, covers a broad spectrum 

including: the advanced inorganic-organic-hybrid polymeric 

materials,high functional sensor, and microbial fuel cells. The 

book is suitable for the researchers working in the areas of 

polymer, nanotechnology, ceramic engineering, engineering 

thermoplastic, energy and power engineering,chemical engineering 

and materials, etc.

图书封面

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