Nanocoatings and ultra-thin films : technologies and applications

Coatings are used for a wide range of applications, from anti-fogging coatings for glass through to corrosion control in the aerospace and automotive industries. Nanocoatings and ultra-thin films provides an up-to-date review of the fundamentals, processes of deposition, characterisation and applications of nanocoatings. Part one covers technologies used in the creation and analysis of thin films, including chapters on current and advanced coating technologies in industry, nanostructured thin films from amphiphilic molecules, chemical and physical vapour deposition methods and methods for analysing nanocoatings and ultra-thin films. Part two focuses on the applications of nanocoatings and ultra-thin films, with chapters covering topics such as nanocoatings for architectural glass, packaging applications, conventional and smart nanocoatings for corrosion protection in aerospace engineering and ultra-thin membranes for sensor applications. With its distinguished editors and international team of contributors, Nanocoatings and ultra-thin films is an essential reference for professional engineers in the glazing, consctruction, electronics and transport industries, as well as all those with an academic research interest in the field.

Contributor contact details Introduction Part I: Technologies Chapter 1: Current and advanced coating technologies for industrial applications Abstract: 1.1 Introduction 1.2 Electro-and electroless chemical plating 1.3 Conversion coatings 1.4 Chemical and physical vapor deposition (CVD and PVD) 1.5 Spray coating 1.6 Other coating techniques 1.7 New lightweight materials 1.8 Trends in environmentally friendly coatings, self-assembling and self-cleaning coatings 1.9 Trends in nanocoatings 1.10 New composite and powder coatings 1.11 Advanced polymers and fillers 1.12 Developments in coating processes 1.13 Acknowledgements Chapter 2: Nanostructured thin films from amphiphilic molecules Abstract: 2.1 Langmuir monolayer 2.2 Amphiphilic polymers 2.3 Dendrons and dendrimers 2.4 Metal/semiconductor nanoparticles 2.5 2-D arrays of colloidal spheres 2.6 Conclusions 2.7 Acknowledgements Chapter 3: Chemical and physical vapor deposition methods for nanocoatings Abstract: 3.1 Substrate preparation for ultra-thin films and functional graded nanocoatings 3.2 Paradigm of functional graded layer-by-layer coating fabrication 3.3 Nanocoating fabrication methods 3.4 Physical vapor deposition-based technologies 3.5 Chemical vapor deposition-based technologies 3.6 Conclusion and future trends Chapter 4: Surface-initiated polymerisation for nanocoatings Abstract: 4.1 Introduction 4.2 Physisorption and chemisorption, equilibrium and irreversible adsorption 4.3 Preparation of surface-bound polymer layers 4.4 Properties and applications 4.5 Acknowledgement Chapter 5: Methods for analysing nanocoatings and ultra-thin films Abstract: 5.1 Introduction 5.2 Electrochemical methods 5.3 Surface-sensitive analytical methods for ultra-thin film coatings 5.4 Spectroscopic, microscopic and acoustic techniques for ultra-thin film coatings 5.5 Conclusions 5.6 Acknowledgements Part II: Applications Chapter 6: Conventional and advanced coatings for industrial applications: an overview Abstract: 6.1 Introduction 6.2 Conventional coating technologies for the automotive and aerospace industries 6.3 Advanced coating technologies for the automotive and aerospace industries 6.4 Packaging applications 6.5 Coatings for the electronics and sensors industry 6.6 Paints and enamels industry 6.7 Biomedical implants industry 6.8 Acknowledgements Chapter 7: Nanocoatings for architectural glass Abstract: 7.1 Introduction 7.2 Spectrally selective glass 7.3 Dynamic smart glazings 7.4 Glass surface protections 7.5 Conclusion 7.6 Acknowledgements Chapter 8: Nanocoatings and ultra-thin films for packaging applications Abstract: 8.1 Introduction 8.2 Nanomaterials in packaging 8.3 High barrier packaging 8.4 Anti-microbial packaging 8.5 Nanosensors in packaging 8.6 Packaging as a drug carrier and for drug delivery 8.7 Nanotechnology solutions for the packaging waste problem 8.8 Anti-static packaging applications 8.9 Regulation and ethical issues in the new packaging industry 8.10 Future trends Chapter 9: Advanced protective coatings for aeronautical applications Abstract: 9.1 Introduction: corrosion in aeronautical structures 9.2 Types of corrosion in aircraft 9.3 Factors influencing corrosion 9.4 Corrosion of aluminum and its alloys 9.5 Corrosion of magnesium alloys 9.6 Protective coatings in aerospace engineering 9.7 Pre-treatments 9.8 Anodizing coatings 9.9 Functional nanocoatings in aerospace engineering 9.10 Nanocoatings for detection of corrosion and mechanical damage 9.11 Self-healing coatings: nanostructured coatings with triggered responses for corrosion protection 9.12 Application of nanomaterials for protection of aeronautical structures 9.13 Conclusion and future trends Chapter 10: Nanoimprint lithographic (NIL) techniques for electronics applications Abstract: 10.1 Lithography techniques and nanoimprint lithography (NIL) fundamentals 10.2 Thermoplastic and laser-assisted NIL 10.3 Photo-assisted nanoimprinting 10.4 Soft NIL 10.5 Extensions of soft NIL 10.6 Scanning probe lithography (SPL) 10.7 Edge lithography 10.8 NIL for three-dimensional (3D) patterning 10.9 Combined nanoimprint approaches 10.10 Applications 10.11 Conclusions 10.12 Acknowledgement Chapter 11: Ultra-thin membranes for sensor applications Abstract: 11.1 Introduction 11.2 Graphene and related two-dimensional (2D) structures 11.3 Nanometer-thick membranes of layered semiconductor compounds 11.4 Ultra-thin membranes of gallium nitride 11.5 Conclusion 11.6 Acknowledgement Chapter 12: Nanocoatings for tribological applications Abstract: 12.1 Introduction 12.2 Use of nanostructured coatings in tribology 12.3 Review of nanostructured coatings for friction and wear applications 12.4 Advanced techniques for characterizing tribological properties of nanostructured coatings 12.5 Conclusions and future trends 12.6 Acknowledgements Chapter 13: Self-cleaning smart nanocoatings Abstract: 13.1 Introduction: TiO2 photocatalysis 13.2 Photocatalysis processes 13.3 The photocatalytic cleaning effect of TiO2-coated materials 13.4 New and smart applications of TiO2 coatings 13.5 Conclusions Index