Advanced coatings materials. (2018)
- Record Type:
- Book
- Title:
- Advanced coatings materials. (2018)
- Main Title:
- Advanced coatings materials
- Further Information:
- Note: Ashutosh Tiwari.
- Authors:
- Tiwari, Ashutosh, 1978-
- Editors:
- Li, Liang
Yang, Qing - Contents:
- Preface xvii Part I: Materials and Methods: Design and Fabrication 1 1 The Science of Molecular Precursor Method 3; Hiroki Nagai and Mitsunobu Sato 1.1 Metal Complex 4 1.2 Molecular Precursor Method 6 1.3 Counter Ion (Stability) 6 1.4 Conversion Process from Precursor Film to Oxide Thin Film 8 1.5 Anatase–Rutile Transformation Controlled by Ligand 8 1.6 Homogeneity 11 1.7 Miscibility 13 1.8 Coatability (Thin Hydroxyapatite Coating of Ti Fiber Web Scaffolds) 13 1.9 Oxygen-Deficient Rutile Thin Films 15 1.10 Cu Thin Film 16 1.11 Applications Using the Molecular Precursor Method 20 1.12 Conclusion 22 References 23 2 Cold Spray—Advanced Coating Process and 3D Modeling 29; Muhammad Faizan-Ur-Rab, Saden H. Zahiri and Syed H. Masood 2.1 Introduction 30 2.1.1 Cold Spray Equipment 31 2.1.1.1 CGT KINETIKS 3000 CS System 31 2.1.1.2 Plasma Giken PCS 1000 System 32 2.1.1.3 Impact Innovations ISS 5/8 and 5/11 CS Systems 33 2.1.2 Applications of Cold Spray Coatings 35 2.2 3D Numerical Modeling of Cold Spray Coating 36 2.2.1 Computational Domain and Boundary Conditions in Numerical Model 37 2.2.2 Three-Dimensional Grid 40 2.2.3 Particle-Fluid Interaction 41 2.3 Experimental Methods of Cold Spray Coatings for Validation of 3D Model 44 2.3.1 Measurement of Substrate’s Temperature 44 2.3.2 Particle Image Velocimetry (PIV) 45 2.4 Results and Discussions 48 2.4.1 3D Model Calibration 48 2.4.2 Effect of Propellant Gas 51 2.4.3 Effect of Nozzle Length 53 2.4.4 Particle’s Temperature 56 2.5Preface xvii Part I: Materials and Methods: Design and Fabrication 1 1 The Science of Molecular Precursor Method 3; Hiroki Nagai and Mitsunobu Sato 1.1 Metal Complex 4 1.2 Molecular Precursor Method 6 1.3 Counter Ion (Stability) 6 1.4 Conversion Process from Precursor Film to Oxide Thin Film 8 1.5 Anatase–Rutile Transformation Controlled by Ligand 8 1.6 Homogeneity 11 1.7 Miscibility 13 1.8 Coatability (Thin Hydroxyapatite Coating of Ti Fiber Web Scaffolds) 13 1.9 Oxygen-Deficient Rutile Thin Films 15 1.10 Cu Thin Film 16 1.11 Applications Using the Molecular Precursor Method 20 1.12 Conclusion 22 References 23 2 Cold Spray—Advanced Coating Process and 3D Modeling 29; Muhammad Faizan-Ur-Rab, Saden H. Zahiri and Syed H. Masood 2.1 Introduction 30 2.1.1 Cold Spray Equipment 31 2.1.1.1 CGT KINETIKS 3000 CS System 31 2.1.1.2 Plasma Giken PCS 1000 System 32 2.1.1.3 Impact Innovations ISS 5/8 and 5/11 CS Systems 33 2.1.2 Applications of Cold Spray Coatings 35 2.2 3D Numerical Modeling of Cold Spray Coating 36 2.2.1 Computational Domain and Boundary Conditions in Numerical Model 37 2.2.2 Three-Dimensional Grid 40 2.2.3 Particle-Fluid Interaction 41 2.3 Experimental Methods of Cold Spray Coatings for Validation of 3D Model 44 2.3.1 Measurement of Substrate’s Temperature 44 2.3.2 Particle Image Velocimetry (PIV) 45 2.4 Results and Discussions 48 2.4.1 3D Model Calibration 48 2.4.2 Effect of Propellant Gas 51 2.4.3 Effect of Nozzle Length 53 2.4.4 Particle’s Temperature 56 2.5 Conclusion 59 References 60 3 Effects of Laser Process Parameters on Overlapped Multipass/Multitrack Hardened Bead Parameters of Ti-6Al-4V Titanium Alloy Using Continuous-Wave Rectangular Beam 65; D.S. Badkar 3.1 Introduction 66 3.2 Experimental Methodology 70 3.2.1 Principle of Rectangular Beam 70 3.2.2 Materials Used and Experimental Set-Up 70 3.2.3 Fixture Fabrication 73 3.2.3.1 Bottom Plate 74 3.2.3.2 The Top Plate 75 3.2.4 Specimen Preparation 76 3.2.5 Phase Transformations of Ti-6Al-4V During Laser Transformation Hardening 78 3.2.5.1 Laser Heating 78 3.2.5.2 Cooling or Self Quenching 78 3.3 Results and Discussion 78 3.3.1 Effect of Laser Process Parameters on Overlapped Multipass/Multitrack Hardened Bead Parameters 78 3.4 Conclusions 82 Acknowledgment 82 References 82 4 Dimensionally Stable Lead Dioxide Anodes Electrodeposited from Methanesulfonate Electrolytes: Physicochemical Properties and Electrocatalytic Reactivity in Oxygen Transfer Reactions 85; Olesia Shmychkova, T. Luk’yanenko and A. Velichenko 4.1 Introduction 86 4.2 Chemical Composition of Coatings 89 4.3 Electrocatalytical Properties of Materials 95 4.3.1 p-Nitroaniline Oxidation 98 4.3.2 p-Nitrophenol Oxidation 100 4.3.3 Oxidation of Salicylic Acid and its Derivatives 101 4.4 Electrode Endurance Tests 108 4.5 Conclusions 116 References 118 5 Polycrystalline Diamond Coating Protects Zr Cladding Surface Against Corrosion in Water-Cooled Nuclear Reactors: Nuclear Fuel Durability Enhancement 123; Irena Kratochvílová, Radek Škoda, Andrew Taylor, Jan Škarohlíd, Petr Ashcheulov and František Fendrych 5.1 Introduction 124 5.2 Zr Alloy Surface Corrosion—General Description 128 5.3 Growth of Polycrystalline Diamond as Anticorrosion Coating on Zr Alloy Surface 131 5.4 Properties of PCD-Coated Zr Alloy Samples Processed in Autoclave 135 5.4.1 Oxidation of Autoclave-Processed PCD-Coated Zr Samples 135 5.4.2 Composition Changes of PCD-Coated Zr Alloy Compared to Autoclaved Zr Alloy and PCD-Coated Zr Alloy 137 5.4.2.1 Capacitance Measurements, NanoESCA, X-Ray-Photoelectron Spectroscopy, Neutron Transmission, and Mass Spectrometry 137 5.4.2.2 Raman, SEM, and SIMS Analysis of the Autoclave-Processed Samples 143 5.4.3 Mechanical and Tribological Properties of Autoclaved PCD Layer-Covered Zr Alloy 145 5.4.4 Radiation Damage Test of Autoclaved PCD-Covered Zr Alloy Sample: Ion Beam Irradiation 147 5.5 PCD Coating Increases Operation Safety and Prolongs the Zr Nuclear Fuel Cladding Lifetime—Overall Summaries 148 5.6 Conclusion 153 Acknowledgments 154 References 154 6 High-Performance WC-Based Coatings for Narrow and Complex Geometries 157; Satish Tailor, Ankur Modi and S. C.Modi 6.1 Introduction 157 6.2 Experimental 159 6.2.1 Feedstock Powder 159 6.2.2 Substrate Preparation and Coating Deposition 159 6.2.3 Why Choosing 45° and 70° Angles to Design the Connectors 163 6.2.4 Characterizations 163 6.3 Results and Discussion 164 6.3.1 Coating Mechanism Behind the Uniform Coating Properties at Both Spray Angles 45° and 70° 164 6.3.2 Coating Microstructures 164 6.3.3 Microhardness of the “As-Sprayed” Coatings 166 6.3.4 X-Ray Diffraction 167 6.3.5 Residual Stress Analysis 169 6.3.6 Adhesion Strength of the Coatings 171 6.4 Conclusions 172 References 172 Part II: Coating Materials Nanotechnology 175 7 Nanotechnology in Paints and Coatings 177; Emmanuel Rotimi Sadiku, Oluranti Agboola, Ibrahim David Ibrahim, Peter Apata Olubambi, BabulReddy Avabaram, Manjula Bandla, Williams Kehinde Kupolati, Jayaramudu Tippabattini, Kokkarachedu Varaprasad, Stephen Chinenyeze Agwuncha, Jonas Mochane, Oluyemi Ojo Daramola, Bilainu Oboirien, Taoreed Adesola Adegbola, Clara Nkuna, Sheshan John Owonubi, Victoria Oluwaseun Fasiku, Blessing Aderibigbe, Vincent Ojijo, Regan Dunne, Koena Selatile, Gertude Makgatho, Caroline Khoathane, Wshington Mhike, Olusesan Frank Biotidara, Mbuso Kingdom Dludlu, AO Adeboje, Oladimeji Adetona Adeyeye, Abongile Ndamase, Samuel Sanni, Gomotsegang Fred Molelekwa, Periyar Selvam, Reshma Nambiar, Anand Babu Perumal, Jarugula Jayaramudu, Nnamdi Iheaturu, Ihuoma Diwe and Betty Chima 7.1 Introduction 178 7.1.1 Paint and Coating 178 7.1.2 Nanopaints and Nanocoatings 180 7.1.2.1 Some Uses of Nanopaints in Different Materials 181 7.1.2.2 Nanomaterials in Paints 183 7.1.3 Types of Nanocoating 189 7.1.3.1 Superhydrophobic Coating 190 7.1.3.2 Oleophobic/Hydrophobic Coating 191 7.1.3.3 Hydrophilic Coatings 191 7.1.3.4 Ceramic, Metal and Glass Coatings 192 7.2 Application of Nanopaints and Nanocoating in the Automotive Industry 195 7.3 Application of Nanopaints and Nanocoating in the Energy Sector 196 7.4 Application of Nanocoating in Catalysis 198 7.5 Application of Nanopaints and Nanocoating in the Marine Industry 200 7.6 Applications of Nanopaints and Nanocoating in the Aerospace Industry 200 7.7 Domestic and Civil Engineering Applications of Nanopaints and Coating 202 7.8 Medical and Biomedical Applications of Nanocoating 205 7.8.1 Antibacterial Applications of Nanocoating 205 7.9 Defense and Military Applications of Nanopaints and Coatings 227 7.10 Conclusion 228 7.11 Future Trend 228 References 229 8 Anodic Oxide Nanostructures: Theories of Anodic Nanostructure Self-Organization 235; Naveen Verma, Jitender Jindal, Krishan Chander Singh and Anuj Mittal 8.1 Introduction 235 8.2 Anodization 237 8.3 Barrier-Type Anodic Metal Oxide Films 237 8.4 Porous-Type Anodic Metal Oxide Films 238 8.5 Theories or Models of Growth Kinetics of Anodic Oxide Films and Fundamental Equations for High-Field Ionic Conductivity 239 8.5.1 Guntherschulze and Betz Model 239 8.5.2 Cabrera and Mott Model 240 8.5.3 Verwey … (more)
- Edition:
- 1st
- Publisher Details:
- Hoboken : Wiley-Scrivener
- Publication Date:
- 2018
- Extent:
- 1 online resource
- Subjects:
- 667.9
Coatings
Coating processes - Languages:
- English
- ISBNs:
- 9781119407645
- Related ISBNs:
- 9781119407638
- Notes:
- Note: Description based on CIP data; resource not viewed.
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- Legal Deposit; Only available on premises controlled by the deposit library and to one user at any one time; The Legal Deposit Libraries (Non-Print Works) Regulations (UK).
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- Restricted: Printing from this resource is governed by The Legal Deposit Libraries (Non-Print Works) Regulations (UK) and UK copyright law currently in force.
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- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library HMNTS - ELD.DS.356351
- Ingest File:
- 01_317.xml