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Biopolymer composites in electronics /
| Clasificación: | Libro Electrónico |
|---|---|
| Otros Autores: | |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Amsterdam :
Elsevier,
2016, �2017.
|
| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- 7.5
- Starch Based
- 7.6
- Carrageenan Based
- 7.7
- Pullulan Based
- 7.8
- Heparin Based
- 8
- Challenges and Future Trends
- 9
- Conclusions
- References
- 6
- Biopolymer Composites in Fuel Cells
- 1
- Introduction
- 1.1
- Polymer Electrolyte Membranes for Fuel Cell Applications
- 1.2
- Biopolymers
- 2
- Chitosan and Its Composites Preparation Methods
- 2.1
- Sulfonation
- 2.2
- Phosphorylation
- 2.3
- Quaternization
- 2.4
- Chemical Crosslinking
- 3
- Chitosan and Its Composite for PEM Fuel Cell Applications
- 3.1
- Chitosan-Inorganic Composite Membranes for PEM Fuel Cell Applications
- 3.2
- Chitosan-Polymer Composite Blend Membranes for PEM Fuel Cell Applications
- 3.3
- Chitosan for Intermediate Temperature PEM Fuel Cell Applications
- 4
- Alginate-Based Membranes PEM Fuel Cell Applications
- 5
- Chitosan for PEM Fuel Cell Electrode Applications
- 6
- Biopolymers for Other Fuel Cell Membrane Applications
- 7
- Challenges to Meet Out
- 8
- Summary and Future Perspective
- References
- 7
- Biopolymer Composites in Field-Effect Transistors
- 1
- Introduction
- 2
- Working of FETs
- 3
- Applications of FETs
- 3.1
- Insulators and Dielectric Materials
- 3.2
- Semiconductors
- 3.3
- Packaging Materials
- 3.4
- Biodegradable Electronic Devices
- 3.5
- Biosensors
- 3.5.1
- DNA-Modified Field-Effect Devices
- 3.5.2
- Enzyme-Based Field-Effect Devices
- 3.5.3
- Electroimmunological-Based Field-Effect Devices
- 3.5.4
- Field-Effect Devices for Live-Cell Responses
- 3.5.5
- Field-Effect Device for Disease Diagnosis
- 4
- Conclusions
- References
- 8
- Development of Microwave Absorbers From Biopolymer Composites
- 1
- Introduction
- 1.1
- Plasma (In Physics)
- 1.2
- Mafo Systemtech Gmbh & Co KG
- 1.3
- Transparency
- 1.4
- Scholten-Honig Research
- 1.5
- Heat Stabilizers
- 1.6
- Chemistry of Microwaves.
- 2
- Biopolymers Composites: An Overview
- 3
- Natural Biopolymers Composites: A Microwave Approach
- 3.1
- Cellulose
- 3.1.1
- Functional Modification of Cellulose
- 3.1.2
- Extraction Cellulose
- 3.2
- Chitin- and Chitosan Derivatives
- 3.3
- Heparin
- 3.4
- Silk
- 3.5
- Gelatin and Its Derivatives
- 4
- Synthetic Biopolymer Composites: A Microwave Approach
- 4.1
- Beta-Pinene
- 4.2
- Poly(ester) Biomaterials
- 5
- Biopolymer Composites: An Endless Source of Application
- 5.1
- Drug Delivery
- 5.2
- Tissue Engineering
- 5.3
- Bone Implantation, Medicinal Devices, and Imaging
- 6
- Conclusions
- References
- 9
- Biopolymer Composites for Electromagnetic Interference Shielding
- 1
- Introduction
- 2
- EMI Shielding Mechanism
- 3
- Shield Requirements and Materials for EMI Shielding
- 3.1
- Review on Biopolymer Composites as EMI Shielding Material
- 4
- Conclusions
- References
- 10
- Biopolymer Composites in Light Emitting Diodes
- 1
- Introduction
- 2
- LEDs
- 2.1
- Inorganic LED
- 2.2
- PLEDs and OLEDs
- 3
- Graphene and Carbon Nanotube-Based LEDs
- 3.1
- Graphene-Based LEDs
- 3.2
- CNT-Based LEDs
- 4
- Bio-OLEDs
- 4.1
- DNA-Based Biocomposite on OLEDs
- 4.2
- Cellulose-Based Biocomposite on OLEDs
- 4.3
- Application of Wood Cellulose Nanocomposite on OLEDs
- 4.4
- Bacterial Cellulose Membrane in form of Biocomposite Polymer on OLEDS
- 4.5
- Photoluminescence-Based Biocomposite on OLEDs
- 5
- Conclusions and Challenges
- References
- 11
- Multifunctional Smart Biopolymer Composites as Actuators
- 1
- Introduction
- 2
- EAPap
- 2.1
- Fabrication
- 2.2
- Actuation Principle
- 2.3
- Physical Properties
- 2.4
- Piezoelectric Properties
- 3
- Ionic EAPap
- 3.1
- Conducting Polymers-Coated EAPap
- 3.2
- PEO/PEG-Blended EAPap
- 3.3
- Chitosan-Blended EAPap
- 3.4
- Ionic Liquid-Dispersed EAPap.
- 4
- Hybrid EAPap
- 4.1
- Carbon Nanotubes-Blended EAPap
- 4.2
- Zinc Oxide-Coated EAPap
- 5
- Conclusions
- Acknowledgment
- References
- 12
- Piezo- and Thermoelectric Materials From Biopolymer Composites
- 1
- Introduction
- 2
- Basics
- 2.1
- Piezoelectricity
- 2.2
- Thermoelectricity
- 3
- Biopolymer Nanocomposites as Piezoelectric Materials
- 4
- Biopolymer Nanocomposites as Thermoelectric Materials
- 5
- Conclusions
- Acknowledgment
- References
- 13
- Development of Biosensors From Biopolymer Composites
- 1
- Introduction
- 2
- Biosensors
- 2.1
- Types of Biosensors
- 2.2
- Prerequisite for Biosensor
- 3
- Biopolymers
- 3.1
- Biocompatibility
- 3.2
- Immobilization Matrix
- 3.3
- Bioresponsiveness
- 3.4
- Demerits of Biopolymers
- 4
- Biopolymer Composites
- 4.1
- Nanoparticle-Based Biopolymer Composites
- 4.2
- Carbon-Based Biopolymer Composites
- 4.3
- Biopolymer Composites Based on Oxides and Other Materials
- 4.4
- Polymer-Based Biopolymer Composites
- 5
- Biorecognition Element
- 5.1
- Enzymatic Biosensors
- 5.1.1
- Enzyme Immobilization
- 5.1.1.1
- Physical adsorption
- 5.1.1.2
- Covalent binding
- 5.1.1.3
- Physical entrapment
- 5.1.1.4
- Crosslinking
- 5.2
- Nucleic Acid-Based Biosensors
- 5.3
- Aptamer-Based Biosensors
- 5.4
- Antibody-Based Biosensors
- 5.5
- Whole Cell-Based Biosensors
- 6
- Current Developments and Future Perspective
- References
- 14
- Development of Vapor/Gas Sensors From Biopolymer Composites
- 1
- Introduction
- 2
- Fabrication of Transducers of Gas/Vapor Sensor Devices
- 2.1
- Fundamentals of Gas Sensors
- 2.2
- Synthesis of Carbon Nanoparticle-Modified Biopolymers
- 2.2.1
- Carbon Black-Based Biopolymer Composites
- 2.2.2
- CNT-Based Biopolymer Composites
- 2.3
- DNA- and Polysaccharide-Modified Carbon Nanotubes.
- 2.4
- Hybridization of Conductive Polymers With Biopolymers.