Buch, Englisch, 628 Seiten, Format (B × H): 155 mm x 231 mm, Gewicht: 1116 g
Current and Future Applications
Buch, Englisch, 628 Seiten, Format (B × H): 155 mm x 231 mm, Gewicht: 1116 g
ISBN: 978-0-85709-211-3
Verlag: Elsevier Science
This book provides an overview of the fabrication methods for anti-abrasive nanocoatings. The connections among fabrication parameters, the characteristics of nanocoatings and the resulting properties (i.e. nanohardness, toughness, wear rate, load-bearing ability, friction coefficient, and scratch resistance) are discussed. Size-affected mechanical properties of nanocoatings are examined, including their uses. Anti-abrasive nanocoatings, including metallic-, ceramic-, and polymeric-based layers, as well as different kinds of nanostructures, such as multi-layered nanocomposites and thin films, are reviewed.
Autoren/Hrsg.
Fachgebiete
- Technische Wissenschaften Technik Allgemein Nanotechnologie
- Technische Wissenschaften Verfahrenstechnik | Chemieingenieurwesen | Biotechnologie Technologie der Oberflächenbeschichtung
- Technische Wissenschaften Maschinenbau | Werkstoffkunde Technische Mechanik | Werkstoffkunde Materialwissenschaft: Biomaterialien, Nanomaterialien, Kohlenstoff
Weitere Infos & Material
- List of figures
- List of tables
- About the editor
- About the contributors
- Preface
- Part One - 1. Wear, friction and prevention of tribo-surfaces by coatings/nanocoatings - 1.1 Introduction
- 1.2 Friction of materials
- 1.3 Wear in metals, alloys and composites
- 1.4 Materials and their selection for wear and friction applications
- 1.5 Coatings/nanocoatings and surface treatments
- 1.6 Conclusion
- Acknowledgements
- References
- 2. An investigation into the tribological property of coatings on micro- and nanoscale - 2.1 Drivers of studying the origin of tribology behavior
- 2.2 Contact at nanometer scale
- 2.3 Atomic friction with zero separation
- 2.4 Scratching wear at atomic scale
- 2.5 Conclusion
- References
- 3. Stress on anti-abrasive performance of sol-gel derived nanocoatings - 3.1 Classical curvature stress for thin films on plate substrates
- 3.2 Thermal stress of thin films
- 3.3 Why do drying films crack?
- 3.4 Cracks by stress come from constraint of shrinkage by the substrate
- 3.5 Rapid sol-gel fabrication to confront tensile trailing cracks
- 3.6 Anti-abrasive SiO2 film in application: self-assembling covalently bonded nanocoating
- 3.7 Abrasive test
- 3.8 Anti-abrasive performance of sol-gel nanocoatings
- 3.9 Conclusion
- Acknowledgments
- References
- 4. Self-cleaning glass - 4.1 Introduction
- 4.2 History of glass
- 4.3 Self-cleaning glass
- 4.4 Hydrophilic coating
- 4.5 Anti-reflective coating
- 4.6 Porous materials
- 4.7 Photocatalytic activity of TiO2
- 4.8 Hydrophobic coatings
- 4.9 Fabrication of self-cleaning glass
- 4.10 Application of self-cleaning glasses
- Acknowledgements
- References
- 5. Sol-gel nanocomposite hard coatings - 5.1 Introduction
- 5.2 Sol-gel nanocomposite hard coatings
- 5.3 Mechanical property studies of sol-gel hard coatings on various substrates
- 5.4 Possible applications of hard coatings
- 5.5 Summary
- Acknowledgments
- References
- 6. Process considerations for nanostructured coatings - 6.1 Overview
- 6.2 Anti-reflection coatings
- 6.3 Fluidized bed method
- 6.4 Electroplating
- 6.5 Nanografting
- 6.6 Plasma spray coating
- 6.7 Nanostructuring in thin films
- 6.8 Electrochemical deposition
- 6.9 Anti-corrosion coating
- 6.10 Infrared transparent electromagnetic shielding
- 6.11 Underlying science - self-assembly
- 6.12 Conclusions
- References
- Part Two - 7. Nanostructured electroless nickel-boron coatings for wear resistance - 7.1 Introduction
- 7.2 Synthesis of electroless nickel-boron coatings
- 7.3 Morphology and structure of electroless nickel-boron coatings
- 7.4 Mechanical and wear properties of nanocrystalline electroless nickel-boron coatings
- 7.5 Corrosion resistance
- 7.6 Conclusion
- References
- 8. Wear resistance of nanocomposite coatings - 8.1 Introduction
- 8.2 Materials and methods
- 8.3 Results and discussion
- 8.4 Conclusions
- Acknowledgments
- References
- 9. Machining medical grade titanium alloys using nonabrasive nanolayered cutting tools - 9.1 Metallurgical Aspects
- 9.2 Machining of titanium alloys
- 9.3 Machining with coated cutting tools: a case study
- 9.4 Conclusions
- Acknowledgments
- References
- 10. Functional nanostructured coatings via layer-by-layer self-assembly - 10.1 Introduction
- 10.2 LbL process
- 10.3 LbL-deposited nanostructured coatings with different functions
- 10.4 Conclusions
- Acknowledgment
- References
- 11. Theoretical study on an influence of fabrication parameters on the quality of smart nanomaterials - 11.1 Introduction
- 11.2 Literature survey on VO2
- 11.3 Synthesis techniques description
- 11.4 Conclusion
- References
- 12. Formation of dense nanostructured coatings by microarc oxidation method - 12.1 Introduction
- 12.2 Phenomena of MAO-coating formation
- 12.3 Voltage-current characteristics
- 12.4 Discussion about growth mechanism of MAO coating
- 12.5 Model of fractal growth of the dense wear-resistant layer
- 12.6 Macro- and microstructure of MAO coatings
- 12.7 Wear-resistant properties
- 12.8 Conclusion
- References
- 13. Current trends in molecular functional monolayers - 13.1 Introduction
- 13.2 Steps for self-assembly
- 13.3 Mechanism
- 13.4 Characterization of SAMs
- 13.5 Use of SAMs for various applications
- 13.6 Self-assembled monolayers on gold substrates
- 13.7 Si-C monolayer formation and C-C bonding
- 13.8 Supramolecular assembly on surface-host-guest interactions and other non-covalent bonding
- 13.9 Self-assembled monolayers on other surfaces such as titania nanotubes
- 13.10 Chemical and electrical biosensors
- 13.11 Quality improvement
- 13.12 Conclusions
- References
- 14. Surface engineered nanostructures on metallic biomedical materials for anti-abrasion - 14.1 Introduction
- 14.2 Surface technologies on metallic biomedical materials for anti-abrasion
- 14.3 Future prospects
- References
- 15. Theoretical modeling of friction and wear processes at atomic level - 15.1 Introduction
- 15.2 MD method
- 15.3 Quantum chemistry methods
- 15.4 Basic types of problems
- 15.5 Lubrication and one-electron transfers
- 15.6 Conclusion
- References
- 16. Mechanical characterization of thin films by depth-sensing indentation - 16.1 Introduction
- 16.2 Hardness
- 16.3 Young's modulus
- 16.4 Conclusion
- Acknowledgements
- References
- Part Three - 17. Advanced bulk and thin film materials for harsh environment MEMS applications - 17.1 Introduction
- 17.2 Piezoelectric substrates
- 17.3 Non-piezoelectric substrates
- 17.4 Thin piezoelectric films
- 17.5 Metal electrodes
- 17.6 Conclusion
- References
- 18. Plasma-assisted techniques for growing hard nanostructured coatings: An overview - 18.1 Introduction
- 18.2 Hard nanocoatings: from history to designs and properties
- 18.3 Main plasma-based techniques for synthesis of hard nanocoatings
- 18.4 Conclusion
- Acknowledgments
- References
- 19. Thermal spray nanostructured ceramic and metal-matrix composite coatings - 19.1 Introduction
- 19.2 Nanostructured feedstock
- 19.3 Nanostructured coatings
- 19.4 Proven applications
- 19.5 Possible future applications
- 19.6 Summary
- Acknowledgements
- References
- 20. Thermally sprayed nanostructured coatings for anti-wear and TBC applications: State-of-the-art and future perspectives - 20.1 Introduction
- 20.2 Thermal spraying processes
- 20.3 Typical nanostructured coatings for technological applications
- 20.4 Conclusion
- References
- 21. Hard thin films: Applications and challenges - 21.1 Introduction
- 21.2 Characterization of thin films
- 21.3 Challenges
- 21.4 Summary
- References
- Index
