Mechanical Properties of Engineered MaterialsFeaturing in-depth discussions on tensile and compressive properties, shear properties, strength, hardness, environmental effects, and creep crack growth, "Mechanical Properties of Engineered Materials" considers computation of principal stresses and strains, mechanical testing, plasticity in ceramics, metals, intermetallics, and polymers, materials selection for thermal shock resistance, the analysis of failure mechanisms such as fatigue, fracture, and creep, and fatigue life prediction. It is a top-shelf reference for professionals and students in materials, chemical, mechanical, corrosion, industrial, civil, and maintenance engineering; and surface chemistry. |
From inside the book
Page iii
... intermetallics , polymers , and their composites ) . Basic concepts are discussed generically , except in cases where they apply only to specific types / classes of materials . Following a brief introduction to materials science and ...
... intermetallics , polymers , and their composites ) . Basic concepts are discussed generically , except in cases where they apply only to specific types / classes of materials . Following a brief introduction to materials science and ...
Page xi
... Intermetallics 385 12.6 Fracture of Ceramics 387 12.7 Fracture of Polymers 389 12.8 Fracture of Composites 393 12.9 Quantitative Fractography 396 12.10 Thermal Shock Response 12.11 Summary Bibliography 397 410 411 13 Toughening ...
... Intermetallics 385 12.6 Fracture of Ceramics 387 12.7 Fracture of Polymers 389 12.8 Fracture of Composites 393 12.9 Quantitative Fractography 396 12.10 Thermal Shock Response 12.11 Summary Bibliography 397 410 411 13 Toughening ...
Page 15
... Intermetallics Intermetallics are compounds formed between different metals . The bonds are often mixed metallic and covalent bonds . However , most intermetallics are often metallic - like in character . Intermetallics are , therefore ...
... Intermetallics Intermetallics are compounds formed between different metals . The bonds are often mixed metallic and covalent bonds . However , most intermetallics are often metallic - like in character . Intermetallics are , therefore ...
Page 20
... intermetallics , and semiconductors and composites ) were introduced . The chapter then concluded with an introduction to structural length scales related to nanostructure , microstructure , and macrostructure . BIBLIOGRAPHY Ashby ...
... intermetallics , and semiconductors and composites ) were introduced . The chapter then concluded with an introduction to structural length scales related to nanostructure , microstructure , and macrostructure . BIBLIOGRAPHY Ashby ...
Page 52
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Contents
XC | 287 |
XCII | 289 |
XCIII | 290 |
XCIV | 292 |
XCV | 295 |
XCVI | 300 |
XCVII | 302 |
XCVIII | 304 |
33 | |
XI | 51 |
XII | 57 |
XIV | 59 |
XVII | 64 |
XVIII | 70 |
XIX | 72 |
XX | 75 |
XXI | 78 |
XXII | 81 |
XXIII | 84 |
XXV | 85 |
XXVI | 86 |
XXVII | 89 |
XXVIII | 93 |
XXIX | 103 |
XXX | 107 |
XXXI | 109 |
XXXII | 110 |
XXXIII | 111 |
XXXIV | 112 |
XXXV | 113 |
XXXVI | 121 |
XXXVII | 128 |
XXXVIII | 131 |
XXXIX | 133 |
XL | 136 |
XLI | 138 |
XLII | 139 |
XLIV | 141 |
XLV | 142 |
XLVI | 144 |
XLVII | 148 |
XLVIII | 156 |
XLIX | 157 |
L | 163 |
LI | 165 |
LII | 169 |
LIII | 173 |
LIV | 175 |
LVI | 177 |
LVII | 178 |
LVIII | 181 |
LIX | 183 |
LX | 187 |
LXI | 188 |
LXII | 191 |
LXIII | 193 |
LXIV | 202 |
LXV | 206 |
LXVI | 209 |
LXVII | 216 |
LXVIII | 218 |
LXIX | 221 |
LXXI | 224 |
LXXII | 225 |
LXXIII | 226 |
LXXIV | 229 |
LXXV | 231 |
LXXVI | 234 |
LXXVII | 244 |
LXXVIII | 245 |
LXXIX | 246 |
LXXXI | 248 |
LXXXII | 249 |
LXXXIII | 257 |
LXXXIV | 262 |
LXXXV | 265 |
LXXXVI | 267 |
LXXXVII | 271 |
LXXXVIII | 275 |
LXXXIX | 282 |
XCIX | 308 |
C | 313 |
CII | 315 |
CIII | 317 |
CV | 318 |
CVI | 320 |
CVII | 324 |
CVIII | 342 |
CIX | 351 |
CX | 355 |
CXI | 359 |
CXII | 361 |
CXIV | 366 |
CXV | 367 |
CXVI | 369 |
CXVII | 371 |
CXVIII | 385 |
CXIX | 387 |
CXX | 389 |
CXXI | 393 |
CXXII | 396 |
CXXIII | 397 |
CXXIV | 410 |
CXXV | 411 |
CXXVI | 414 |
CXXVII | 416 |
CXXVIII | 418 |
CXXIX | 419 |
CXXX | 426 |
CXXXI | 436 |
CXXXII | 440 |
CXXXIII | 442 |
CXXXIV | 443 |
CXXXV | 445 |
CXXXVII | 446 |
CXXXVIII | 449 |
CXXXIX | 451 |
CXL | 452 |
CXLI | 456 |
CXLII | 460 |
CXLIII | 462 |
CXLIV | 467 |
CXLV | 473 |
CXLVI | 474 |
CXLVII | 477 |
CXLVIII | 480 |
CXLIX | 486 |
CL | 493 |
CLI | 496 |
CLII | 499 |
CLIII | 504 |
CLIV | 505 |
CLV | 511 |
CLVI | 513 |
CLVII | 520 |
CLVIII | 523 |
CLIX | 525 |
CLX | 528 |
CLXI | 531 |
CLXII | 533 |
CLXIII | 542 |
CLXIV | 544 |
CLXV | 546 |
CLXVI | 547 |
CLXVII | 548 |
CLXVIII | 556 |
CLXIX | 562 |
CLXX | 567 |
CLXXI | 568 |
CLXXII | 573 |
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Common terms and phrases
Acta Metall alloys atoms axial bonds brittle Burgers vector ceramics closure components composite materials constant corresponds crack tip creep deformation crystal curve debonding defects density dependence diffusion dislocation motion displacement ductile edge dislocation effects engineering equations Evans expressions failure fatigue crack growth fiber FIGURE fracture mechanics fracture toughness Furthermore given grain boundary hardening Hence important to note increasing initial interactions interfaces intermetallics lattice linear elastic martensite matrix composites Mech Metall Mater microcracks microstructure modulus nucleation obtained occur parameter particles Pergamon Press permission from Pergamon phase plane strain plastic deformation polymers precipitates processes properties ratio regime reinforcement Reprinted with permission result Schematic illustration schematically in Fig screw dislocation shear stress shown in Fig slip plane Soboyejo solid solution specimen steel strain rate strength strengthening stress intensity factor stress-strain structures temperature tensile tensor thermal shock tion titanium toughening transformation volume fraction Young's modulus zone