All Stories

  1. A review of Long fibre thermoplastic (LFT) composites
  2. Void Characterization
  3. Cellular Materials
  4. Intrinsic Voids in Polymers
  5. Preface
  6. Introduction
  7. Applications
  8. Metal Matrix Composites
  9. Processing
  10. Cyclic Fatigue
  11. Monotonic Behavior
  12. Micromechanics
  13. Interface
  14. Matrix Materials
  15. Reinforcements
  16. Introduction
  17. Applications
  18. Creep
  19. Wear and Corrosion
  20. Introduction
  21. Automotive Composites
  22. Composite Materials
  23. Nonconventional Composites
  24. Reinforcements
  25. Matrix Materials
  26. Introduction
  27. Interfaces
  28. Designing with Composites
  29. Carbon Fiber/Carbon Matrix Composites
  30. Polymer Matrix Composites
  31. Monotonic Strength and Fracture
  32. Fatigue and Creep
  33. Ceramic Matrix Composites
  34. Metal Matrix Composites
  35. Micromechanics of Composites
  36. Multifilamentary Superconducting Composites
  37. Macromechanics of Composites
  38. Characterization of fatigue behavior of long fiber reinforced thermoplastic (LFT) composites
  39. Frontmatter
  40. Index
  41. Effect of Mounting Material Compliance on Nanoindentation Response of Metallic Materials
  42. Two-dimensional microstructure based modelling of Young's modulus of long fibre thermoplastic composite
  43. Preface to special section on composite materials
  44. Indentation mechanics and fracture behavior of metal/ceramic nanolaminate composites
  45. Mechanical Behavior of Materials
  46. Editorial
  47. Metal-matrix composites in ground transportation
  48. Metal Matrix Composites
  49. Electrophoretic Deposition of Carbon Nanotubes on Metallic Surfaces
  50. Electrophoretic Deposition of Carbon Nanotubes on Metallic Surfaces
  51. Microstructure-based modeling of the deformation behavior of particle reinforced metal matrix composites
  52. Mechanical Behavior of Multilayered Nanoscale Metal-Ceramic Composites
  53. The cyclic fatigue of high-performance fibers
  54. Processing and Microstructure of an All-Oxide Ceramic Composite
  55. Processing and Microstructure of an All-Oxide Ceramic Composite
  56. Monotonic and Cyclic Fatigue Behavior of High-Performance Ceramic Fibers
  57. Deformation behavior of (Cu, Ag)–Sn intermetallics by nanoindentation
  58. Composite Foams
  59. Metal-Matrix Composites
  60. Young’s modulus of (Cu, Ag)–Sn intermetallics measured by nanoindentation
  61. Ceramic Matrix Composites
  62. Macromechanics
  63. Applications
  64. Interface
  65. Introduction
  66. Processing of Ceramic Matrix Composites
  67. Micromechanics: Elastic, Thermal, and Physical Properties
  68. Thermal Stresses
  69. Ceramic Reinforcements
  70. Interface Mechanics and Toughness
  71. Ceramic Matrix Materials
  72. FIBER FRACTURE: AN OVERVIEW
  73. Thermal-shock behavior of a Nicalon-fiber-reinforced hybrid glass-ceramic composite
  74. Axial fatigue behavior of binder-treated versus diffusion alloyed powder metallurgy steels
  75. Monotonic and Cyclic Fatigue Behavior of a High Performance Ceramic Fiber
  76. Fibrous Reinforcements for Composites: Overview
  77. Glass Fibers
  78. Metal-Matrix Composites
  79. Thermal Cycling, Thermal Aging and Thermal Shock Behavior of Nicalon-Fiber Reinforced Glass Matrix Composites
  80. Preface
  81. Metallic fibers
  82. Introduction
  83. Ceramic fibers
  84. Carbon fibers
  85. Fibers and fiber products
  86. Experimental determination of fiber properties
  87. Statistical treatment of fiber strength
  88. Suggested further reading
  89. Fibrous materials
  90. Composite Materials
  91. Interfaces
  92. Introduction
  93. Reinforcements
  94. Matrix Materials
  95. Designing with Composites
  96. Monotonic Strength and Fracture
  97. Polymer Matrix Composites
  98. Metal Matrix Composites
  99. Ceramic Matrix Composites
  100. Multifilamentary Superconducting Composites
  101. Fatigue and Creep
  102. Macromechanics of Composites
  103. Carbon Fiber Composites
  104. Micromechanics of Composites
  105. Composite materials science and engineering
  106. Composite Materials
  107. Fibers
  108. Interfaces
  109. Introduction
  110. Matrix Materials
  111. Multifilamentary Superconducting Composites
  112. Micromechanics of Composites
  113. Strength, Fracture, Fatigue, and Design
  114. Metal Matrix Composites
  115. Ceramic Matrix Composites
  116. Carbon Fiber Composites
  117. Polymer Matrix Composites
  118. Macromechanics of Composites
  119. Composite Materials — ICCM V
  120. Composite Materials: Some Recent Developments
  121. MATRIX BEHAVIOR IN COPPER--TUNGSTEN COMPOSITES AT SMALL STRAINS.
  122. Glass fibers
  123. References
  124. Natural polymeric fibers
  125. Synthetic polymeric fibers
  126. Some important units and conversion factors
  127. Elasticity and Viscoelasticity
  128. Plasticity
  129. Fracture: Macroscopic Aspects
  130. Fracture: Microscopic Aspects
  131. Fracture Testing
  132. Martensitic Transformation
  133. Creep and Superplasticity
  134. Fatigue
  135. Composite Materials
  136. Environmental Effects
  137. Appendixes