Functional Materials and Advanced Manufacturing

Functional Materials and Advanced Manufacturing

by Chander Prakash, Sunpreet Singh, J. Paulo Davim
Released January 2021
Publisher(s): CRC Press
ISBN: 9781000193206

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Book description

This three-volume set addresses a new knowledge of function materials, their processing, and their characterizations.

Table of contents

  1. Cover
  2. Volume 1
    1. Cover
    2. Half Title
    3. Series Page
    4. Title Page
    5. Copyright Page
    6. Contents
    7. Preface
    8. Editors
    9. Contributors
    10. Chapter 1 Electrochromics for Smart Windows: Oxide-Based Thin Films (1/4)
    11. Chapter 1 Electrochromics for Smart Windows: Oxide-Based Thin Films (2/4)
    12. Chapter 1 Electrochromics for Smart Windows: Oxide-Based Thin Films (3/4)
    13. Chapter 1 Electrochromics for Smart Windows: Oxide-Based Thin Films (4/4)
    14. Chapter 2 Polymeric Biomaterials in Tissue Engineering (1/4)
    15. Chapter 2 Polymeric Biomaterials in Tissue Engineering (2/4)
    16. Chapter 2 Polymeric Biomaterials in Tissue Engineering (3/4)
    17. Chapter 2 Polymeric Biomaterials in Tissue Engineering (4/4)
    18. Chapter 3 Amorphous Semiconductors: Past, Present, and Future (1/6)
    19. Chapter 3 Amorphous Semiconductors: Past, Present, and Future (2/6)
    20. Chapter 3 Amorphous Semiconductors: Past, Present, and Future (3/6)
    21. Chapter 3 Amorphous Semiconductors: Past, Present, and Future (4/6)
    22. Chapter 3 Amorphous Semiconductors: Past, Present, and Future (5/6)
    23. Chapter 3 Amorphous Semiconductors: Past, Present, and Future (6/6)
    24. Chapter 4 Promise of Self-lubricating Aluminum-Based Composite Material (1/4)
    25. Chapter 4 Promise of Self-lubricating Aluminum-Based Composite Material (2/4)
    26. Chapter 4 Promise of Self-lubricating Aluminum-Based Composite Material (3/4)
    27. Chapter 4 Promise of Self-lubricating Aluminum-Based Composite Material (4/4)
    28. Chapter 5 Energy Materials and Energy Harvesting (1/6)
    29. Chapter 5 Energy Materials and Energy Harvesting (2/6)
    30. Chapter 5 Energy Materials and Energy Harvesting (3/6)
    31. Chapter 5 Energy Materials and Energy Harvesting (4/6)
    32. Chapter 5 Energy Materials and Energy Harvesting (5/6)
    33. Chapter 5 Energy Materials and Energy Harvesting (6/6)
    34. Chapter 6 Advanced Processing of Superalloys for Aerospace Industries (1/3)
    35. Chapter 6 Advanced Processing of Superalloys for Aerospace Industries (2/3)
    36. Chapter 6 Advanced Processing of Superalloys for Aerospace Industries (3/3)
    37. Chapter 7 Review on Rheological Behavior of Aluminum Alloys in Semi-Solid State (1/2)
    38. Chapter 7 Review on Rheological Behavior of Aluminum Alloys in Semi-Solid State (2/2)
    39. Chapter 8 Bio-Nanomaterials: An Inevitable Contender in Tissue Engineering (1/7)
    40. Chapter 8 Bio-Nanomaterials: An Inevitable Contender in Tissue Engineering (2/7)
    41. Chapter 8 Bio-Nanomaterials: An Inevitable Contender in Tissue Engineering (3/7)
    42. Chapter 8 Bio-Nanomaterials: An Inevitable Contender in Tissue Engineering (4/7)
    43. Chapter 8 Bio-Nanomaterials: An Inevitable Contender in Tissue Engineering (5/7)
    44. Chapter 8 Bio-Nanomaterials: An Inevitable Contender in Tissue Engineering (6/7)
    45. Chapter 8 Bio-Nanomaterials: An Inevitable Contender in Tissue Engineering (7/7)
    46. Chapter 9 Biomaterials (1/6)
    47. Chapter 9 Biomaterials (2/6)
    48. Chapter 9 Biomaterials (3/6)
    49. Chapter 9 Biomaterials (4/6)
    50. Chapter 9 Biomaterials (5/6)
    51. Chapter 9 Biomaterials (6/6)
    52. Chapter 10 Characterisation and Optimisation of TiO2/CuO Nanocomposite for Effective Dye Degradation from Water under Simulated Solar Irradiation (1/3)
    53. Chapter 10 Characterisation and Optimisation of TiO2/CuO Nanocomposite for Effective Dye Degradation from Water under Simulated Solar Irradiation (2/3)
    54. Chapter 10 Characterisation and Optimisation of TiO2/CuO Nanocomposite for Effective Dye Degradation from Water under Simulated Solar Irradiation (3/3)
    55. Chapter 11 Dual Applicability of Hexagonal Pyramid-Shaped Nitrogen-Doped ZnO Composites As an Efficient Photocatalyst (1/3)
    56. Chapter 11 Dual Applicability of Hexagonal Pyramid-Shaped Nitrogen-Doped ZnO Composites As an Efficient Photocatalyst (2/3)
    57. Chapter 11 Dual Applicability of Hexagonal Pyramid-Shaped Nitrogen-Doped ZnO Composites As an Efficient Photocatalyst (3/3)
    58. Index (1/2)
    59. Index (2/2)
  3. Volume 2
    1. Cover
    2. Half Title
    3. Series Page
    4. Title Page
    5. Copyright Page
    6. Contents
    7. Preface
    8. Editors
    9. Contributors
    10. Chapter 1 A Critical Review on the Machining of Engineering Materials by Die-Sinking EDM (1/5)
    11. Chapter 1 A Critical Review on the Machining of Engineering Materials by Die-Sinking EDM (2/5)
    12. Chapter 1 A Critical Review on the Machining of Engineering Materials by Die-Sinking EDM (3/5)
    13. Chapter 1 A Critical Review on the Machining of Engineering Materials by Die-Sinking EDM (4/5)
    14. Chapter 1 A Critical Review on the Machining of Engineering Materials by Die-Sinking EDM (5/5)
    15. Chapter 2 Optimization of Machining Parameters of High-Speed Toolpath to Achieve Minimum Cycle Time for Ti-6Al-4V (1/5)
    16. Chapter 2 Optimization of Machining Parameters of High-Speed Toolpath to Achieve Minimum Cycle Time for Ti-6Al-4V (2/5)
    17. Chapter 2 Optimization of Machining Parameters of High-Speed Toolpath to Achieve Minimum Cycle Time for Ti-6Al-4V (3/5)
    18. Chapter 2 Optimization of Machining Parameters of High-Speed Toolpath to Achieve Minimum Cycle Time for Ti-6Al-4V (4/5)
    19. Chapter 2 Optimization of Machining Parameters of High-Speed Toolpath to Achieve Minimum Cycle Time for Ti-6Al-4V (5/5)
    20. Chapter 3 A Review of Machinability Aspects of Difficult-to-Cut Materials Using Microtexture Patterns (1/5)
    21. Chapter 3 A Review of Machinability Aspects of Difficult-to-Cut Materials Using Microtexture Patterns (2/5)
    22. Chapter 3 A Review of Machinability Aspects of Difficult-to-Cut Materials Using Microtexture Patterns (3/5)
    23. Chapter 3 A Review of Machinability Aspects of Difficult-to-Cut Materials Using Microtexture Patterns (4/5)
    24. Chapter 3 A Review of Machinability Aspects of Difficult-to-Cut Materials Using Microtexture Patterns (5/5)
    25. Chapter 4 Micromachining (1/9)
    26. Chapter 4 Micromachining (2/9)
    27. Chapter 4 Micromachining (3/9)
    28. Chapter 4 Micromachining (4/9)
    29. Chapter 4 Micromachining (5/9)
    30. Chapter 4 Micromachining (6/9)
    31. Chapter 4 Micromachining (7/9)
    32. Chapter 4 Micromachining (8/9)
    33. Chapter 4 Micromachining (9/9)
    34. Chapter 5 A Review Study on Miniaturization—A Boon or Curse (1/5)
    35. Chapter 5 A Review Study on Miniaturization—A Boon or Curse (2/5)
    36. Chapter 5 A Review Study on Miniaturization—A Boon or Curse (3/5)
    37. Chapter 5 A Review Study on Miniaturization—A Boon or Curse (4/5)
    38. Chapter 5 A Review Study on Miniaturization—A Boon or Curse (5/5)
    39. Chapter 6 A Comprehensive Review on Similar and Dissimilar Metal Joints by Friction Welding (1/3)
    40. Chapter 6 A Comprehensive Review on Similar and Dissimilar Metal Joints by Friction Welding (2/3)
    41. Chapter 6 A Comprehensive Review on Similar and Dissimilar Metal Joints by Friction Welding (3/3)
    42. Chapter 7 3D Bioprinting in Pharmaceuticals, Medicine, and Tissue Engineering Applications (1/4)
    43. Chapter 7 3D Bioprinting in Pharmaceuticals, Medicine, and Tissue Engineering Applications (2/4)
    44. Chapter 7 3D Bioprinting in Pharmaceuticals, Medicine, and Tissue Engineering Applications (3/4)
    45. Chapter 7 3D Bioprinting in Pharmaceuticals, Medicine, and Tissue Engineering Applications (4/4)
    46. Chapter 8 Investigating on the Lapping and Polishing Process of Cylindrical Rollers (1/5)
    47. Chapter 8 Investigating on the Lapping and Polishing Process of Cylindrical Rollers (2/5)
    48. Chapter 8 Investigating on the Lapping and Polishing Process of Cylindrical Rollers (3/5)
    49. Chapter 8 Investigating on the Lapping and Polishing Process of Cylindrical Rollers (4/5)
    50. Chapter 8 Investigating on the Lapping and Polishing Process of Cylindrical Rollers (5/5)
    51. Chapter 9 NiTi Thin-Film Shape Memory Alloys and Their Industrial Application (1/5)
    52. Chapter 9 NiTi Thin-Film Shape Memory Alloys and Their Industrial Application (2/5)
    53. Chapter 9 NiTi Thin-Film Shape Memory Alloys and Their Industrial Application (3/5)
    54. Chapter 9 NiTi Thin-Film Shape Memory Alloys and Their Industrial Application (4/5)
    55. Chapter 9 NiTi Thin-Film Shape Memory Alloys and Their Industrial Application (5/5)
    56. Chapter 10 Carbon Fibers: Surface Modification Strategies and Biomedical Applications (1/4)
    57. Chapter 10 Carbon Fibers: Surface Modification Strategies and Biomedical Applications (2/4)
    58. Chapter 10 Carbon Fibers: Surface Modification Strategies and Biomedical Applications (3/4)
    59. Chapter 10 Carbon Fibers: Surface Modification Strategies and Biomedical Applications (4/4)
    60. Index (1/2)
    61. Index (2/2)
  4. Volume 3
    1. Cover
    2. Half Title
    3. Series Page
    4. Title Page
    5. Copyright Page
    6. Contents
    7. Preface
    8. Editors
    9. Contributors
    10. Chapter 1 Wear Measuring Devices for Biomaterials (1/3)
    11. Chapter 1 Wear Measuring Devices for Biomaterials (2/3)
    12. Chapter 1 Wear Measuring Devices for Biomaterials (3/3)
    13. Chapter 2 Closed Form Solution for the Vibrational Analysis of Metal–Ceramic-Based Porous Functionally Graded Plate (1/4)
    14. Chapter 2 Closed Form Solution for the Vibrational Analysis of Metal–Ceramic-Based Porous Functionally Graded Plate (2/4)
    15. Chapter 2 Closed Form Solution for the Vibrational Analysis of Metal–Ceramic-Based Porous Functionally Graded Plate (3/4)
    16. Chapter 2 Closed Form Solution for the Vibrational Analysis of Metal–Ceramic-Based Porous Functionally Graded Plate (4/4)
    17. Chapter 3 Functionally Graded Structures: Design and Analysis of Tailored Advanced Composites (1/5)
    18. Chapter 3 Functionally Graded Structures: Design and Analysis of Tailored Advanced Composites (2/5)
    19. Chapter 3 Functionally Graded Structures: Design and Analysis of Tailored Advanced Composites (3/5)
    20. Chapter 3 Functionally Graded Structures: Design and Analysis of Tailored Advanced Composites (4/5)
    21. Chapter 3 Functionally Graded Structures: Design and Analysis of Tailored Advanced Composites (5/5)
    22. Chapter 4 Heat Transfer in Noncircular Microchannels Using Water and Ethylene Glycol as Base Fluids with Zn and ZnO Nanoparticles (1/4)
    23. Chapter 4 Heat Transfer in Noncircular Microchannels Using Water and Ethylene Glycol as Base Fluids with Zn and ZnO Nanoparticles (2/4)
    24. Chapter 4 Heat Transfer in Noncircular Microchannels Using Water and Ethylene Glycol as Base Fluids with Zn and ZnO Nanoparticles (3/4)
    25. Chapter 4 Heat Transfer in Noncircular Microchannels Using Water and Ethylene Glycol as Base Fluids with Zn and ZnO Nanoparticles (4/4)
    26. Chapter 5 Inufluence of Layer Thickness and Orientation on Tensile Strength and Surface Roughness of FDM-Built Parts (1/4)
    27. Chapter 5 Inufluence of Layer Thickness and Orientation on Tensile Strength and Surface Roughness of FDM-Built Parts (2/4)
    28. Chapter 5 Inufluence of Layer Thickness and Orientation on Tensile Strength and Surface Roughness of FDM-Built Parts (3/4)
    29. Chapter 5 Inufluence of Layer Thickness and Orientation on Tensile Strength and Surface Roughness of FDM-Built Parts (4/4)
    30. Chapter 6 Effect of Process Parameters on Cutting Forces and Osteonecrosis for Orthopedic Bone Drilling Applications (1/4)
    31. Chapter 6 Effect of Process Parameters on Cutting Forces and Osteonecrosis for Orthopedic Bone Drilling Applications (2/4)
    32. Chapter 6 Effect of Process Parameters on Cutting Forces and Osteonecrosis for Orthopedic Bone Drilling Applications (3/4)
    33. Chapter 6 Effect of Process Parameters on Cutting Forces and Osteonecrosis for Orthopedic Bone Drilling Applications (4/4)
    34. Chapter 7 Fabrication and Machining Methods of Composites for Aerospace Applications (1/4)
    35. Chapter 7 Fabrication and Machining Methods of Composites for Aerospace Applications (2/4)
    36. Chapter 7 Fabrication and Machining Methods of Composites for Aerospace Applications (3/4)
    37. Chapter 7 Fabrication and Machining Methods of Composites for Aerospace Applications (4/4)
    38. Chapter 8 Computational Analysis of Aerodynamics Characteristics of High-Speed Moving Vehicle (1/3)
    39. Chapter 8 Computational Analysis of Aerodynamics Characteristics of High-Speed Moving Vehicle (2/3)
    40. Chapter 8 Computational Analysis of Aerodynamics Characteristics of High-Speed Moving Vehicle (3/3)
    41. Chapter 9 Role of Finite Element Analysis in Customized Design of Kid’s Orthotic Product (1/5)
    42. Chapter 9 Role of Finite Element Analysis in Customized Design of Kid’s Orthotic Product (2/5)
    43. Chapter 9 Role of Finite Element Analysis in Customized Design of Kid’s Orthotic Product (3/5)
    44. Chapter 9 Role of Finite Element Analysis in Customized Design of Kid’s Orthotic Product (4/5)
    45. Chapter 9 Role of Finite Element Analysis in Customized Design of Kid’s Orthotic Product (5/5)
    46. Chapter 10 An Experimental Study of Mechanical and Microstructural Properties of AA7075-T6 by Using UWFSW Process (1/6)
    47. Chapter 10 An Experimental Study of Mechanical and Microstructural Properties of AA7075-T6 by Using UWFSW Process (2/6)
    48. Chapter 10 An Experimental Study of Mechanical and Microstructural Properties of AA7075-T6 by Using UWFSW Process (3/6)
    49. Chapter 10 An Experimental Study of Mechanical and Microstructural Properties of AA7075-T6 by Using UWFSW Process (4/6)
    50. Chapter 10 An Experimental Study of Mechanical and Microstructural Properties of AA7075-T6 by Using UWFSW Process (5/6)
    51. Chapter 10 An Experimental Study of Mechanical and Microstructural Properties of AA7075-T6 by Using UWFSW Process (6/6)
    52. Index (1/2)
    53. Index (2/2)

Product information

  • Title: Functional Materials and Advanced Manufacturing
  • Author(s): Chander Prakash, Sunpreet Singh, J. Paulo Davim
  • Release date: January 2021
  • Publisher(s): CRC Press
  • ISBN: 9781000193206