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171031s2018 ne ob 001 0 eng d |
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|a YDX
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|d IDEBK
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|d OCLCQ
|d D6H
|d U3W
|d OCLCF
|d INT
|d ITD
|d OCLCQ
|d UKMGB
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|a 018587881
|2 Uk
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|a 1008873675
|a 1229525516
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|a 9780128095669
|q (electronic bk.)
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|a 0128095660
|q (electronic bk.)
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|z 0128095512
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|z 9780128095515
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|a (OCoLC)1008769101
|z (OCoLC)1008873675
|z (OCoLC)1229525516
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|a TP1180.P65
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|a TEC
|x 009010
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|a 668.4/234
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|a Polyaniline blends, composites, and nanocomposites /
|c edited by P.M. Visakh, Cristina Della Pina, Ermelinda Falletta.
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|a Amsterdam, Netherlands :
|b Elsevier,
|c [2018]
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|c �2018
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|a 1 online resource
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|a text
|b txt
|2 rdacontent
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|a computer
|b c
|2 rdamedia
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|a online resource
|b cr
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|a Online resource; title from PDF title page (EBSCO, viewed November 2, 2017).
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|a Includes bibliographical references and index.
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|a "Polyaniline Blends, Composites, and Nanocomposites summarizes recent advances in polyaniline-based blends, composites and nanocomposites. Polyaniline (PANI) is a conducting polymer with a range of potential applications, particularly in electronics and packaging. The book covers the preparation, characterization and application of PANI-based composites, including the structure-property relationship and modification of PANI. Offers an in-depth update on the major findings and observations in the field of polyaniline-based blends, composites and nanocomposites, with contributions from leading researchers in industry, academia, government and private research institutions worldwide. An application-oriented, practical guide to the development and application of this polymeric material. The book includes discussion of reinforcement of polyaniline via addition of carbon-based materials, blends with thermoplastics, thermosets, natural and synthetic rubber, and polyaniline based composites and nanocomposites, with an emphasis on enabling polymer scientists and engineers to more effectively utilize this material in new applications. Includes an in-depth update on the state of research into this exciting material, with detailed and practical information for developing emerging applications of polyanilineEnables polymer scientists and engineers to overcome challenges and take advantage of opportunities relating to polyaniline, e.g., solubility of the polymer, improving conductivity and moreIncludes detailed coverage of the preparation, characterization and application of PANI-based composites in detail, along with the structure-property relationship and modification of PANI"--
|c Provided by publisher
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|g Machine generated contents note:
|g ch. 1
|t Polyaniline-Based Blends, Composites, and Nanocomposites: State of the Art, New Challenges, and Opportunities /
|r P.M. Visakh --
|g 1.1.
|t Polyaniline: Structure and Properties Relationship --
|g 1.2.
|t Modification of Polyaniline --
|g 1.3.
|t Polyaniline Nano-/Micromaterial -- Based Blends and Composites --
|g 1.4.
|t Polyaniline-Based Thermoplastic Blends --
|g 1.5.
|t Polyaniline-Based Blends: Natural Rubber and Synthetic Rubber --
|g 1.6.
|t Polyaniline-Based Composites and Nanocomposites --
|g 1.7.
|t Characterization of Polyaniline-Based Blends, Composites, and Nanocomposites --
|g 1.8.
|t Polyaniline -- Natural Polymer Composites and Nanocomposites --
|g 1.9.
|t Applications of Polyaniline-Based Blends, Composites, and Nanocomposites --
|g 1.10.
|t Other Applications of Polyaniline-Based Blends, Composites, and Nanocomposites --
|g 1.11.
|t Polyaniline -- Nanomaterial Composites: Structural, Optical, and Electrical Properties --
|t References --
|g ch. 2
|t Polyaniline: Structure and Properties Relationship /
|r Subhendu Bhandari --
|g 2.1.
|t Introduction --
|g 2.2.
|t Structure --
|g 2.3.
|t Polymerization and Manufacture --
|g 2.3.1.
|t Oxidative Chemical Synthesis --
|g 2.3.2.
|t Interfacial Polymerization --
|g 2.3.3.
|t Microemulsion Polymerization --
|g 2.3.4.
|t Solid-State Synthesis --
|g 2.3.5.
|t Electrochemical Polymerization --
|g 2.3.6.
|t Electrospinning --
|g 2.3.7.
|t Enzymatic Synthesis --
|g 2.4.
|t Additives --
|g 2.5.
|t Processing and Suppliers --
|g 2.6.
|t Applications --
|g 2.7.
|t Morphology --
|g 2.8.
|t Crystal Structure and Crystallization Behavior --
|g 2.9.
|t Physical Properties --
|g 2.10.
|t Mechanical Properties --
|g 2.11.
|t Thermal Properties and Flammability --
|g 2.12.
|t Chemical Properties --
|g 2.13.
|t Electrical and Optical Properties --
|g 2.14.
|t Weathering and Radiation Resistance --
|g 2.15.
|t Future and Environmental Impact --
|g 2.16.
|t Conclusions --
|t References --
|g ch. 3
|t Modification of Polyaniline /
|r Tahir Jamil --
|g 3.1.
|t Introduction --
|g 3.2.
|t Gamma and Electron Beam Irradiations --
|g 3.2.1.
|t Principle of the Techniques --
|g 3.2.2.
|t Effects of Irradiation on Polyaniline --
|g 3.2.3.
|t Stabilization of Irradiated Polyaniline --
|g 3.2.4.
|t Solubility of Irradiated Polyaniline --
|g 3.3.
|t Ion Implantation Technique --
|g 3.3.1.
|t Principle of the Technique --
|g 3.3.2.
|t Ion Implantation Methods --
|g 3.3.3.
|t Ion Implantation Species --
|g 3.3.4.
|t Effects and Uses of the Ion Implantation on Polyaniline --
|g 3.4.
|t Conclusions --
|t References --
|g ch. 4
|t Polyaniline Nano-/Micromaterials -- Based Blends and Composites /
|r Mohammad H. Ezzati --
|g 4.1.
|t Introduction --
|g 4.2.
|t Polyaniline Nano-/Micromaterials -- Based Blends --
|g 4.2.1.
|t Solution Blending Method --
|g 4.2.2.
|t Melt Blending Method --
|g 4.3.
|t Polyaniline Nano-/Micromaterials -- Based Composite --
|g 4.3.1.
|t Dispersion Polymerization Method --
|g 4.3.2.
|t Sonochemical Route --
|g 4.3.3.
|t Electrochemical Methods --
|g 4.3.4.
|t In Situ Polymerization Technique --
|g 4.3.5.
|t Emulsion Polymerization Pathway --
|g 4.4.
|t Conclusions --
|t References --
|g ch. 5
|t Polyaniline-Based Thermoplastic Blends /
|r Cynthia Oueiny --
|g 5.1.
|t Introduction --
|g 5.2.
|t Preparation --
|g 5.2.1.
|t In Situ Polymerization of Aniline in a TP Matrix --
|g 5.2.2.
|t Ex Situ Blends --
|g 5.2.3.
|t Electrospinning --
|g 5.2.4.
|t Electrochemical Synthesis --
|g 5.3.
|t Properties --
|g 5.3.1.
|t Morphology --
|g 5.3.2.
|t Transport Properties --
|g 5.3.3.
|t Thermomechanical Properties --
|g 5.3.4.
|t Rheological Properties --
|g 5.4.
|t Applications --
|g 5.4.1.
|t Gas Sensors --
|g 5.4.2.
|t Welding of Plastics --
|g 5.4.3.
|t Corrosion Protection --
|g 5.4.4.
|t Electronic Devices --
|g 5.4.5.
|t Membranes --
|g 5.4.6.
|t Radar Absorbing Materials --
|g 5.5.
|t Conclusions --
|t Abbreviations --
|t References --
|g ch. 6
|t Polyaniline-Based Blends: Natural Rubber and Synthetic Rubber /
|r Masoud Mozafari --
|g 6.1.
|t Introduction --
|g 6.2.
|t Polyaniline-Based Natural Rubber Blends --
|g 6.2.1.
|t Polyaniline/Natural Rubber Composite Fibers --
|g 6.2.2.
|t Natural Rubber/Polyaniline-DBSA Composite --
|g 6.2.3.
|t PANI Blend With ENR-50 --
|g 6.2.4.
|t Polyaniline-Coated Short Nylon Fiber/Natural Rubber --
|g 6.3.
|t Polyaniline-Based Synthetic Rubber Blends --
|g 6.3.1.
|t Polyaniline Blend With Nitrile Rubber --
|g 6.3.2.
|t Polyaniline-Coated Nylon Fiber and Chloroprene Rubber --
|g 6.3.3.
|t Polyaniline/Organoclay Nanocomposite and EPDM Rubber --
|g 6.3.4.
|t Polyaniline/Ethylene Propylene Diene Rubber Blends --
|g 6.3.5.
|t SBS Block Copolymer-Polyaniline Blends --
|g 6.4.
|t Conclusion --
|t References --
|g ch. 7
|t Polyaniline-Based Composites and Nanocomposites /
|r Yongtao Tan --
|g 7.1.
|t Polyaniline -- TiO2 Nanocomposites --
|g 7.1.1.
|t Nanotubes --
|g 7.1.2.
|t Nanoparticles --
|g 7.1.3.
|t Nanowires --
|g 7.1.4.
|t Nanorods --
|g 7.1.5.
|t Nanosheets --
|g 7.2.
|t Polyaniline -- Calcium Carbonate Composites --
|g 7.3.
|t Natural Fiber -- Based Polyaniline Composites --
|g 7.4.
|t Filler-Based Polyaniline Composites --
|g 7.5.
|t Polyaniline -- Silica Nanocomposites --
|g 7.6.
|t Polyaniline -- Clay Nanocomposites --
|g 7.7.
|t Polyaniline -- Manganese Dioxide Nanocomposites --
|g 7.8.
|t Polyaniline-Porous Carbon Composites --
|g 7.9.
|t Polyaniline -- Copper Nanocomposites --
|g 7.10.
|t Polyaniline -- Montmorillonite Nanocomposites --
|g 7.11.
|t Polyaniline -- Graphene Nanocomposites --
|g 7.12.
|t Cellulose Whiskers -- Polyaniline Nanocomposites --
|g 7.13.
|t Conclusions --
|t References --
|g ch. 8
|t Characterization of Polyaniline-Based Blends, Composites, and Nanocomposites /
|r Marco A. De Paoli --
|g 8.1.
|t Introduction --
|g 8.2.
|t Mechanical Properties --
|g 8.3.
|t Dynamic Mechanical Analysis --
|g 8.4.
|t Thermogravimetric Analysis --
|g 8.5.
|t Differential Scanning Calorimetry --
|g 8.6.
|t Scanning Electron Microscopy --
|g 8.7.
|t Atomic Force Microscopy --
|g 8.8.
|t Transmission Electron Microscopy --
|g 8.9.
|t X-ray Diffraction --
|g 8.10.
|t Small Angle X-ray Scattering Analysis --
|g 8.11.
|t Conclusions --
|t Acknowledgments --
|t References --
|g ch. 9
|t Polyaniline/Natural Polymer Composites and Nanocomposites /
|r Kannusamy Pandiselvi --
|g 9.1.
|t Introduction --
|g 9.2.
|t Polyaniline/Cellulose-Based Composites and Nanocomposites --
|g 9.2.1.
|t Cellulose --
|g 9.2.2.
|t Polyaniline/Cellulose Composites --
|g 9.2.3.
|t Polyaniline/Bacterial Cellulose Nanocomposite --
|g 9.2.4.
|t Polyaniline/Modified Cellulose Composites --
|g 9.3.
|t Polyaniline/Chitin-Based Composites and Nanocomposites --
|g 9.3.1.
|t Chitin --
|g 9.3.2.
|t Chitin-Polyaniline Composites --
|g 9.3.3.
|t Chitosan --
|g 9.3.4.
|t Chitosan/Polyaniline Composites --
|g 9.3.5.
|t Applications of Chitosan -- Polyaniline Composites --
|g 9.3.6.
|t Chitosan-Metal Oxide/Polyaniline Composites --
|g 9.4.
|t Polyaniline/Starch-Based Composites and Nanocomposites --
|g 9.4.1.
|t Advantages of Starch/Polyaniline Composite --
|g 9.5.
|t Polyaniline/Seaweed-Based Composites and Nanocomposites --
|g 9.6.
|t Polyaniline/Other Natural Polymer -- Based Composites and Nanocomposites --
|g 9.7.
|t Conclusions --
|t References --
|g ch. 10
|t Applications of Polyaniline-Based Blends, Composites, and Nanocomposites /
|r S.A. Waghuley --
|g 10.1.
|t Introduction --
|g 10.2.
|t Methods of Synthesis of Polyaniline --
|g 10.3.
|t Synthesis of Polyaniline-Based Materials --
|g 10.4.
|t Applications of Polyaniline-Based Composites --
|g 10.4.1.
|t Electronic Applications --
|g 10.4.2.
|t Polyaniline-Based Composite for Conducting Applications --
|g 10.4.3.
|t Polyaniline-Based Composites for Packing Application --
|g 10.5.
|t Conclusions --
|t References --
|t Further Reading --
|g ch. 11
|t Other Applications of Polyaniline-Based Blends, Composites, and Nanocomposites /
|r Shiv K. Sharma --
|g 11.1.
|t Introduction --
|g 11.2.
|t Application in Energy Storage --
|g 11.3.
|t Application in Corrosion --
|g 11.4.
|t Application in Electromagnetic Interference Shielding --
|g 11.5.
|t Application in Polyaniline Composites --
|g 11.6.
|t Major Challenges and Future Scope of Work --
|g 11.7.
|t Conclusion --
|t References --
|g ch.
|
505 |
0 |
0 |
|t 12
|t Polyaniline -- Nanomaterial Composites: Structural, Optical, and Electrical Properties /
|r Ajit Kumar Meikap --
|g 12.1.
|t Introduction --
|g 12.2.
|t Synthesis of Nanomaterials --
|g 12.2.1.
|t Top-Down Approach --
|g 12.2.2.
|t Bottom-Up Approach --
|g 12.2.3.
|t In Situ Polymerization --
|g 12.2.4.
|t Synthesis of PANI/MWCNT-CdS and PANI/MWCNT-ZnS Nanocomposites --
|g 12.3.
|t Characterizations --
|g 12.3.1.
|t Structural --
|g 12.3.2.
|t Optical --
|g 12.3.3.
|t Electrical --
|g 12.4.
|t Conclusions --
|g 12.5.
|t Applications --
|t References.
|
650 |
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0 |
|a Polyethylene
|x Analysis.
|
650 |
|
0 |
|a Composite materials.
|
650 |
|
0 |
|a Nanocomposites (Materials)
|
650 |
|
2 |
|a Nanocomposites
|0 (DNLM)D053761
|
650 |
|
6 |
|a Poly�ethyl�ene
|0 (CaQQLa)201-0030511
|x Analyse.
|0 (CaQQLa)201-0374819
|
650 |
|
6 |
|a Composites.
|0 (CaQQLa)201-0025721
|
650 |
|
6 |
|a Mat�eriaux nanocomposites.
|0 (CaQQLa)000269981
|
650 |
|
7 |
|a composite material.
|2 aat
|0 (CStmoGRI)aat300014627
|
650 |
|
7 |
|a TECHNOLOGY & ENGINEERING
|x Chemical & Biochemical.
|2 bisacsh
|
650 |
|
7 |
|a Composite materials.
|2 fast
|0 (OCoLC)fst00871682
|
650 |
|
7 |
|a Nanocomposites (Materials)
|2 fast
|0 (OCoLC)fst01748679
|
700 |
1 |
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|a P. M., Visakh,
|e editor.
|
700 |
1 |
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|a Della Pina, Cristina,
|e editor.
|
700 |
1 |
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|a Falletta, Ermelinda,
|e editor.
|
776 |
0 |
8 |
|i Print version:
|z 0128095512
|z 9780128095515
|w (OCoLC)983384025
|
856 |
4 |
0 |
|u https://sciencedirect.uam.elogim.com/science/book/9780128095515
|z Texto completo
|