Functional Polymer Coatings : Principles, Methods, and Applications.

Intro -- Title Page -- Copyright Page -- Contents -- Contributors -- Preface -- Chapter 1 Transparent Organic-Inorganic Nanocomposite Coatings -- 1.1 INTRODUCTION -- 1.2 FABRICATION STRATEGIES -- 1.2.1 Blending Method -- 1.2.2 Sol-Gel Process -- 1.2.3 Intercalation Method -- 1.3 MECHANICALLY ENHANCED NANOCOMPOSITE CLEARCOATS -- 1.3.1 Solventborne Polyurethane Nanocomposite Coatings -- 1.3.2 Waterborne Nanocomposite Clearcoats -- 1.3.3 UV-Curable Nanocomposite Coatings -- 1.3.4 Other Mechanically Strong Nanocomposite Coatings -- 1.4 OPTICAL NANOCOMPOSITE COATINGS -- 1.4.1 Transparent UV-Shielding Nanocomposite Coatings -- 1.4.2 High Refractive Index Nanocomposite Coatings -- 1.4.3 Transparent NIR-Shielding Nanocomposite Coatings -- 1.5 TRANSPARENT BARRIER NANOCOMPOSITE COATINGS -- 1.6 TRANSPARENT CONDUCTING NANOCOMPOSITE COATINGS -- 1.7 OTHER FUNCTIONAL NANOCOMPOSITE COATINGS -- 1.8 CONCLUSIONS AND OUTLOOK -- REFERENCES -- Chapter 2 Superhydrophobic and Superoleophobic Polymeric Surfaces -- 2.1 INTRODUCTION -- 2.2 SURFACE WETTABILITY -- 2.3 VARIOUS APPROACHES TO OBTAIN SUPER-REPELLENT SURFACES -- 2.3.1 Template-Replicating Methods -- 2.3.2 Hierarchically Structured Particles -- 2.3.3 LbL Deposition -- 2.3.4 Plasma Treatment -- 2.3.5 Chemical Vapor Deposition -- 2.3.6 Electrospinning -- 2.3.7 Electrochemical Polymerization -- 2.3.8 Other Methods -- 2.4 APPLICATIONS OF SUPER-REPELLENT POLYMERIC SURFACES -- 2.4.1 Self-Cleaning -- 2.4.2 Anti-bioadhesion -- 2.4.3 Anti-Icing -- 2.4.4 Oil-Water Separation -- 2.5 SUMMARY AND OUTLOOK -- ACKNOWLEDGMENTS -- REFERENCES -- Chapter 3 Superhydrophilic and Superamphiphilic Coatings -- 3.1 INTRODUCTION -- 3.2 BASIC CONCEPTS OF SUPERHYDROPHILICITY -- 3.3 NATURALLY OCCURRING SUPERHYDROPHILIC AND SUPERAMPHIPHILIC SURFACES -- 3.4 ARTIFICIAL SUPERHYDROPHILIC COATINGS -- 3.4.1 TiO2 Coatings -- 3.4.2 SiO2 Coatings.

3.5 METHODS FOR FABRICATING SUPERHYDROPHILIC AND SUPERAMPHIPHILIC SURFACES -- 3.5.1 Sol-Gel Method -- 3.5.2 Layer-By-Layer Assembly -- 3.5.3 Electrochemical Methods -- 3.5.4 Electrospinning -- 3.5.5 Etching -- 3.5.6 Plasma Treatment -- 3.5.7 Hydrothermal Method -- 3.5.8 Dip Coating -- 3.5.9 Phase Separation -- 3.5.10 Templating Method -- 3.6 APPLICATIONS -- 3.6.1 Self-Cleaning -- 3.6.2 Antifogging and Antireflective Coatings -- 3.6.3 Antifouling Properties -- 3.6.4 Enhanced Boiling Heat Transfer -- 3.6.5 Efficient Water Evaporation -- 3.6.6 Switchable and Patterned Wettability Coatings -- 3.6.7 Other Applications -- 3.7 COMMERCIAL COATINGS -- 3.8 CONCLUSIONS AND OUTLOOK -- REFERENCES -- Chapter 4 Self-Healing Polymeric Coatings -- 4.1 INTRODUCTION -- 4.1.1 Self-Healing Materials -- 4.1.2 Self-Healing Polymeric Coatings -- 4.2 SELF-HEALING APPROACHES FOR FUNCTIONAL POLYMERIC COATINGS -- 4.2.1 Intrinsic Healing -- 4.2.2 Extrinsic Healing -- 4.3 FUNCTIONALITIES RECOVERY AND POSSIBLE APPLICATIONS -- 4.3.1 Surface Properties: Wettability and Anti-(bio)adhesion -- 4.3.2 Barrier and Corrosion Protection -- 4.3.3 Interfacial Bonding Between Dissimilar Materials -- 4.4 CONCLUDING REMARKS AND CHALLENGES -- ACKNOWLEDGMENTS -- REFERENCES -- Chapter 5 Stimuli-Responsive Polymers as Active Layers for Sensors -- 5.1 INTRODUCTION -- 5.2 STIMULI-RESPONSIVE SOFT MATERIALS -- 5.2.1 Thermally Responsive Polymers -- 5.2.2 Field-Responsive Polymers -- 5.2.3 Biologically Responsive Polymer Systems -- 5.2.4 Multistimuli-Responsive Materials -- 5.2.5 Stimuli-Responsive Hydrogels -- 5.3 SENSORS FROM STIMULI-RESPONSIVE HYDROGEL LAYERS -- 5.3.1 pH Sensors -- 5.3.2 Metal Ion Sensors -- 5.3.3 Humidity Sensors -- 5.3.4 DNA Sensors -- 5.3.5 Glucose Sensors -- 5.4 IONOPHORE-BASED SENSORS -- 5.4.1 Ion-Selective Electrodes -- 5.4.2 Chromoionophores -- 5.4.3 Optodes.

5.4.4 Dynamic Optodes -- 5.5 CHALLENGES AND OPPORTUNITIES -- REFERENCES -- Chapter 6 Self-Stratifying Polymers and Coatings -- 6.1 INTRODUCTION -- 6.2 BASIC CONCEPTS OF SELF-STRATIFICATION -- 6.2.1 Evaporation Effect -- 6.2.2 The Surface Tension Gradient -- 6.2.3 The Substrate-Wetting Force -- 6.2.4 Kinetically Controlled Reactions -- 6.3 CONCLUSIONS -- REFERENCES -- Chapter 7 Surface-Grafted Polymer Coatings: Preparation, Characterization, and Antifouling Behavior -- 7.1 INTRODUCTION -- 7.2 SURFACE-GRAFTING METHODS -- 7.2.1 "Grafting-From" Method -- 7.2.2 "Grafting-To" Method -- 7.3 BEHAVIOR OF SURFACE-GRAFTED POLYMERS -- 7.3.1 Conformation of Grafted Chains -- 7.3.2 Chain Migration -- 7.4 CHARACTERIZATION TECHNIQUES -- 7.4.1 Ellipsometry -- 7.4.2 Contact Angle -- 7.4.3 X-ray Photoelectron Spectroscopy -- 7.4.4 Scanning Probe Microscopies -- 7.5 ANTIFOULING COATINGS -- 7.5.1 Surface-Grafted PEG -- 7.5.2 Surface-Grafted Zwitterionic Polymers -- 7.6 SUMMARY -- REFERENCES -- Chapter 8 Partially Fluorinated Coatings by Surface-Initiated Ring-Opening Metathesis Polymerization -- 8.1 BASIC CONCEPTS -- 8.2 SURFACE CHEMISTRY -- 8.3 KINETICS OF FILM GROWTH -- 8.4 SURFACE ENERGY OF pNBFn FILMS -- 8.5 MICROMOLDING SIP -- 8.6 CONCLUSIONS AND OUTLOOK -- ACKNOWLEDGMENTS -- REFERENCES -- Chapter 9 Fabrication and Application of Structural Color Coatings -- 9.1 INTRODUCTION -- 9.2 GENERAL METHODS OF COLLOIDAL ASSEMBLY -- 9.2.1 Flow-Induced Deposition -- 9.2.2 Field-Induced Deposition -- 9.3 COLLOIDAL ASSEMBLY OF SOFT POLYMER SPHERES -- 9.4 USES OF STRUCTURAL COLORS -- 9.4.1 Photonic Paper -- 9.4.2 Coloring and Protection of Substrates -- 9.4.3 Color Responses -- 9.4.4 Structural Color Coatings with Lotus Effects and Superhydrophilicity -- 9.4.5 Structural Color as Effect Pigments -- 9.5 CONCLUSIONS AND OUTLOOK -- REFERENCES.

Chapter 10 Antibacterial Polymers and Coatings -- 10.1 INTRODUCTION -- 10.2 BASIC CONCEPTS -- 10.2.1 Coatings that Resist Adhesion -- 10.2.2 Coatings that Release Toxins -- 10.3 POLYMERS AND ANTIMICROBIAL COATING BINDERS -- 10.3.1 Polymeric Coatings with QA Groups -- 10.3.2 Polymers with Quaternary Phosphonium Groups -- 10.3.3 Norfloxacin-Containing Polymers -- 10.3.4 Polymeric N-Halamines -- 10.4 ADDITION OF INORGANIC PARTICLES -- 10.4.1 Titanium Dioxide -- 10.4.2 Zinc Oxide -- 10.4.3 Silver Compounds -- 10.5 CONCLUSIONS AND OUTLOOK -- REFERENCES -- Chapter 11 Novel Marine Antifouling Coatings: Antifouling Principles and Fabrication Methods -- 11.1 INTRODUCTION -- 11.2 MARINE BIOFOULING -- 11.3 ENZYME-BASED COATINGS -- 11.4 FOULING RELEASE COATINGS -- 11.4.1 Principles of FR Coatings -- 11.4.2 Hybrid Silicone-Based FR Coatings -- 11.4.3 Fluoropolymer-Based FR Coatings -- 11.5 NONFOULING COATINGS -- 11.5.1 Principles of NF Coatings -- 11.5.2 PEG-Based NF Coatings -- 11.5.3 Poly(Zwitterionic) NF Coatings -- 11.5.4 Other Hydrophilic NF Materials -- 11.6 BIOINSPIRED MICRO-TOPOGRAPHICAL SURFACES -- 11.6.1 AF Principles of Bioinspired Microtopographical Surfaces -- 11.6.2 Approaches to the Production of AF Coatings with Surface Topographies -- 11.7 AMPHIPHILIC NANOSTRUCTURED COATINGS -- 11.7.1 Principles of Amphiphilic Nanostructured Coatings -- 11.7.2 PEG-Fluoropolymers Amphiphilic Coatings -- 11.7.3 Other Amphiphilic AF Polymers -- 11.7.4 Characterization Techniques -- 11.8 SUMMARY -- REFERENCES -- Index -- EULA.

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Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2024. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.