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Chapter One Radiation Sources and Radiation Processing
1£®1 Basic principles of radiation application for advanced material development
1£®2 Gamma ray
1£®3 Electron beam accelerator
1£®3£®1 High energy £¨10 MeV£© electron beam accelerator
1£®3£®2 Middle energy £¨-5 MeV£© electron beam accelerator
1£®3£®3 Middle energy £¨1 - 3 MeV£© electron beam accelerator
1£®3£®4 Low-energy £¨100 - 500 keV£© electron beam accelerator
Reference

Chapter Two Radiation Technology Application in High-Performance Fibers and Functional Textiles
2£®1 Radiation application in carbon fibers and silicon carbide fibers
2£®1£®1 Carbon fibers
2£®1£®2 Silicon carbide fibers
2£®2 Radiation-induced surface modification in advanced fiber composites
2£®2£®1 High-performance fibers and composites
2£®2£®2 Radiation modification of aramid fibers
2£®2£®3 Radiation modification of carbon fiber
2£®3 Radiation grafting and application of ultrahigh molecular weight polyethylene fiber
2£®3£®1 Radiation effects on ultrahigh molecular weight polyethylene fiber
2£®3£®2 Preparation of amidoxime-based UHMWPE fibrous adsorbent for extraction of uranium from seawater
2£®3£®3 Preparation of highly durable conductive UHMWPE fibers
2£®4 Preparation of functional textiles by radiation grafting
2£®4£®1 Types and preparation methods of functional textiles
2£®4£®2 Advantages of preparing functional textiles by radiation grafting
2£®4£®3 Current status of preparation of functional textiles by radiation grafting
References

Chapter Three Radiation Cross-Linking and Its Application
3£®1 Radiation cross-linked wire/cable and heat-shrinkable materials
3£®1£®1 Radiation cross-linked wire/cable
3£®1£®2 Radiation cross-linked heat-shrinkable materials
3£®2 Radiation cross-linked polyolefin shrink film
3£®3 Application of radiation vulcanization in rubber and tires
3£®3£®1 Radiation vulcanization of rubber
3£®3£®2 Application of radiation technology in tires
3£®4 Radiation vulcanization of natural rubber latex and synthetic rubber latex
3£®4£®1 Radiation vulcanization of natural rubber latex
3£®4£®2 Radiation vulcanization of synthetic rubber latex
References

Chapter Four Radiation Cross-Linking for Conventional and Supereritieal CO2 Foaming of Polymer
4£®1 Introduction of microporous foaming material
4£®2 Preparation of microporous polymers using supercritical
4£®3 Supercritical CO2 foaming of rubber and ester polymer
4£®4 Radiation cross-linking foaming technology
4£®4£®1 Radiation cross-linking for the polymer of foaming
4£®4£®2 Radiation cross-linking foaming
4£®4£®3 Radiation cross-linking foaming of polypropylene
References

Chapter Five Radiation Degrmtation or Modification of Polytetrafluoroethylene and Natural Polymers
5£®1 Radiation degradation£¬ cross-linking£¬ and surface modification of polytetrafluoroethylene
5£®1£®1 Structure and properties of polytetrafluoroethylene
5£®1£®2 Radiation degradation and cross-linking of polytetrafluoroethylene
5£®1£®3 Surface modification of polytetrafluoroethylene
5£®2 Polymer uhrafine powder fabrication by radiation
5£®2£®1 Polytetrafluoroethylene ultrafine powder
5£®2£®2 Other ultrafine powders
5£®3 Radiation modification of polysaccharides and their derivatives
5£®3£®1 Radiation grafting and applications
5£®3£®2 Radiation cross-linking and application
References

Chapter Six Radiation Emulsion Polymerization
6£®1 Emulsion polymerization
6£®l£®1 History and features of emulsion polymerization
6£®1£®2 Fundamental theory of emulsion polymerization
6£®1£®3 Radiation emulsion polymerization
6£®2 Typical application examples of radiation emulsion polymerization
6£®2£®1 Radiation emulsion polymerization of vinyl acetate
6£®2£®2 Preparation of polymer composite by radiation emulsion polymerization
6£®2£®3 Radiation emulsion copolymerization
6£®2£®4 Radiation emulsifier-free emulsion polymerization
6£®2£®5 Other progress in radiation emulsion polymerization
6£®3 Pigment printing hinder prepared by radiation emulsion polymerization
6£®3£®1 Representative basic formula for pigment printing hinder
6£®3£®2 Processing
6£®4 Polyacrylate thickeners prepared by radiation emulsion polymerization
6£®4£®1 Typical basic formula
6£®4£®2 Operation flow
6£®5 Advantages and disadvantages of radiation emulsion polymerization technique
References

Chapter Seven Radiation-Grafted Membranes for Applications in Renewable Energy Technology
7£®1 Ion-exchange membrane and radiation-induced grafting copolymerization
7£®1£®1 Ion-exchange membrane
7£®1£®2 Methods of radiation-induced copolymerization
7£®2 Nature of polymer matrix
7£®3 Radiation-grafted membrane
7£®3£®1 Cation-exchange membrane
7£®3£®2 Anion-exchange membrane
7£®3£®3 Amphoteric ion-exchange membrane
7£®4 Applications in renewable energy technology
7£®4£®1 Radiation-grafted membrane for vanadium redox battery
7£®4£®2 Radiation-grafted membrane for fuel cell
7£®4£®3 Application of radiation-grafted film in proton exchange membrane fuel cells
7£®4£®4 Application of radiation-grafted membranes in alkaline ftiel cells
References

Chapter Eight Radiation Preparation or Application of Graphene£¬ Nanonaterials£¬ Porous Polymeric Materials£¬ and Ionic Liquids
8£®1 Radiation preparation and application of graphene and its nanocomposites
8£®1£®1 Preparation and application of radiation-reduced graphene oxide
8£®1£®2 Radiation preparation and application of graphene-metal nanocomposites
8£®1£®3 Radiation preparation and application of graphene-polymer nanocomposites
8£®1£®4 Radiation preparation and application of graphene oxide-polymer nanocomposites
8£®2 Preparation of nanomaterials by radiation technology
8£®2£®1 Preparation of metal nanoparticles
8£®2£®2 Preparation of nanocomposite materials
8£®3 Preparation of porous polymeric materials using radiation technique
8£®3£®1 Porous polymeric microspheres prepared via radiation-initiated seeded emulsion polymerization
8£®3£®2 Interconnected porous polymer materials prepared via radiation-initiated polymerization in high internal phase emulsions
8£®4 Radiation effects of ionic liquids
8£®4£®1 Radiation effect on imidazolium ionic liquids
8£®4£®2 Radiation effect on imidazolium ionic liquid extraction systems
8£®4£®3 Influence of radiation on the extraction ability of ionic liquid extraction systems
8£®4£®4 Radiation synthesis of poly£¨ionic liquids£© gels for metal ion removal
References
Index