Modern Physical Metallurgy and Materials EngineeringFor many years, various editions of Smallman's Modern Physical Metallurgy have served throughout the world as a standard undergraduate textbook on metals and alloys. In 1995, it was rewritten and enlarged to encompass the related subject of materials science and engineering and appeared under the title Metals & Materials: Science, Processes, Applications offering a comprehensive amount of a much wider range of engineering materials. Coverage ranged from pure elements to superalloys, from glasses to engineering ceramics, and from everyday plastics to in situ composites, Amongst other favourable reviews, Professor Bhadeshia of Cambridge University commented: "Given the amount of work that has obviously gone into this book and its extensive comments, it is very attractively priced. It is an excellent book to be recommend strongly for purchase by undergraduates in materials-related subjects, who should benefit greatly by owning a text containing so much knowledge." The book now includes new chapters on materials for sports equipment (golf, tennis, bicycles, skiing, etc.) and biomaterials (replacement joints, heart valves, tissue repair, etc.) - two of the most exciting and rewarding areas in current materials research and development. As in its predecessor, numerous examples are given of the ways in which knowledge of the relation between fine structure and properties has made it possible to optimise the service behaviour of traditional engineering materials and to develop completely new and exciting classes of materials. Special consideration is given to the crucial processing stage that enables materials to be produced as marketable commodities. Whilst attempting to produce a useful and relatively concise survey of key materials and their interrelationships, the authors have tried to make the subject accessible to a wide range of readers, to provide insights into specialised methods of examination and to convey the excitement of the atmosphere in which new materials are conceived and developed. |
Contents
II | 6 |
III | 6 |
IV | 6 |
V | 6 |
VI | 7 |
VII | 9 |
VIII | 11 |
IX | 12 |
CXLVIII | 216 |
CXLIX | 217 |
CLI | 218 |
CLII | 220 |
CLIII | 221 |
CLIV | 222 |
CLV | 223 |
CLVIII | 224 |
X | 13 |
XI | 16 |
XII | 18 |
XIII | 21 |
XIV | 22 |
XV | 24 |
XVII | 26 |
XIX | 27 |
XX | 30 |
XXI | 31 |
XXII | 32 |
XXIII | 35 |
XXIV | 36 |
XXV | 38 |
XXVI | 42 |
XXVII | 43 |
XXVIII | 44 |
XXIX | 45 |
XXX | 46 |
XXXI | 47 |
XXXII | 48 |
XXXIII | 49 |
XXXIV | 52 |
XXXV | 56 |
XXXVI | 58 |
XXXVII | 59 |
XXXVIII | 60 |
XXXIX | 64 |
XL | 73 |
XLI | 76 |
XLIII | 79 |
XLIV | 80 |
XLV | 81 |
XLVI | 82 |
XLVIII | 84 |
XLIX | 86 |
L | 87 |
LI | 89 |
LII | 90 |
LIII | 91 |
LV | 92 |
LVI | 95 |
LVII | 97 |
LIX | 98 |
LX | 99 |
LXI | 104 |
LXII | 105 |
LXIII | 106 |
LXIV | 108 |
LXV | 112 |
LXVI | 113 |
LXVII | 115 |
LXVIII | 116 |
LXIX | 117 |
LXX | 119 |
LXXII | 125 |
LXXIII | 126 |
LXXIV | 127 |
LXXV | 133 |
LXXVII | 134 |
LXXVIII | 135 |
LXXIX | 138 |
LXXX | 142 |
LXXXI | 143 |
LXXXII | 144 |
LXXXIII | 146 |
LXXXIV | 150 |
LXXXV | 152 |
LXXXVI | 154 |
LXXXVIII | 155 |
LXXXIX | 157 |
XCI | 158 |
XCII | 160 |
XCIII | 161 |
XCVI | 162 |
XCVII | 163 |
XCVIII | 164 |
C | 165 |
CII | 168 |
CIII | 170 |
CIV | 171 |
CVI | 172 |
CVII | 174 |
CVIII | 175 |
CIX | 176 |
CX | 177 |
CXI | 178 |
CXII | 179 |
CXIII | 181 |
CXV | 183 |
CXVI | 185 |
CXVII | 187 |
CXVIII | 188 |
CXIX | 189 |
CXXI | 191 |
CXXII | 192 |
CXXIII | 193 |
CXXV | 194 |
CXXVI | 195 |
CXXVII | 196 |
CXXIX | 197 |
CXXX | 199 |
CXXXIII | 200 |
CXXXV | 201 |
CXXXVI | 203 |
CXXXVIII | 204 |
CXXXIX | 205 |
CXLI | 206 |
CXLII | 207 |
CXLIII | 208 |
CXLIV | 209 |
CXLV | 211 |
CXLVI | 212 |
CXLVII | 214 |
CLX | 226 |
CLXI | 232 |
CLXII | 235 |
CLXIII | 236 |
CLXIV | 237 |
CLXV | 239 |
CLXVI | 242 |
CLXVII | 243 |
CLXVIII | 245 |
CLXX | 247 |
CLXXI | 249 |
CLXXIII | 251 |
CLXXIV | 252 |
CLXXVI | 254 |
CLXXVII | 256 |
CLXXVIII | 258 |
CLXXIX | 259 |
CLXXXI | 263 |
CLXXXII | 265 |
CLXXXIII | 268 |
CLXXXIV | 271 |
CLXXXV | 272 |
CLXXXVI | 273 |
CLXXXVII | 274 |
CLXXXVIII | 276 |
CLXXXIX | 278 |
CXC | 282 |
CXCII | 283 |
CXCIII | 284 |
CXCIV | 285 |
CXCV | 288 |
CXCVI | 289 |
CXCVII | 291 |
CXCIX | 292 |
CC | 293 |
CCII | 294 |
CCIII | 295 |
CCIV | 297 |
CCV | 298 |
CCVI | 299 |
CCVII | 300 |
CCVIII | 301 |
CCIX | 302 |
CCX | 303 |
CCXI | 305 |
CCXII | 306 |
CCXIII | 307 |
CCXIV | 308 |
CCXV | 310 |
CCXVI | 312 |
CCXVIII | 314 |
CCXIX | 315 |
CCXX | 316 |
CCXXII | 317 |
CCXXIV | 320 |
CCXXV | 321 |
CCXXVI | 322 |
CCXXVII | 323 |
CCXXVIII | 325 |
CCXXIX | 330 |
CCXXX | 331 |
CCXXXI | 334 |
CCXXXII | 337 |
CCXXXIII | 345 |
CCXXXIV | 346 |
CCXXXVI | 348 |
CCXXXVII | 351 |
CCXXXIX | 352 |
CCXL | 353 |
CCXLI | 354 |
CCXLII | 355 |
CCXLIII | 356 |
CCXLIV | 357 |
CCXLV | 358 |
CCXLVI | 359 |
CCXLVII | 360 |
CCXLVIII | 361 |
CCXLIX | 366 |
CCL | 376 |
CCLI | 382 |
CCLII | 387 |
CCLIII | 388 |
CCLIV | 391 |
CCLVI | 394 |
CCLVII | 395 |
CCLVIII | 396 |
CCLIX | 397 |
CCLXI | 398 |
CCLXII | 399 |
CCLXV | 400 |
CCLXVI | 401 |
CCLXVII | 402 |
CCLXIX | 403 |
CCLXXII | 404 |
CCLXXIV | 405 |
CCLXXV | 406 |
CCLXXVI | 407 |
CCLXXVII | 408 |
CCLXXVIII | 409 |
CCLXXIX | 410 |
CCLXXXI | 411 |
CCLXXXV | 412 |
CCLXXXVI | 413 |
CCLXXXVII | 414 |
CCLXXXIX | 415 |
CCXCII | 416 |
CCXCIV | 417 |
CCXCVI | 418 |
CCXCVII | 420 |
CCXCVIII | 422 |
424 | |
427 | |
Other editions - View all
Modern Physical Metallurgy and Materials Engineering R. E. Smallman,R J Bishop No preview available - 1999 |
Common terms and phrases
alloys alumina aluminium annealing applied atoms austenite beam behaviour bonding Burgers vector carbide carbon cations cell ceramics chemical components composition concentration cooling copper corrosion crack creep cross-slip curve decreases defects deformation density developed diagram diffraction diffusion ductility effect elastic electrical electrons elements equation equilibrium eutectic fatigue fibres formation fracture free energy glass grain boundary graphite growth hardening heat increases interface interstitial ions lattice layer liquid martensite materials matrix mechanical melt metals modulus molecules nitride nucleation nucleus occurs orientation oxide particles pearlite phase plastic polymers precipitate produced properties quenched ratio reaction regions resistance screw dislocation shear stress shown in Figure silicon single crystals slip plane solid solution solute atoms specimen stacking fault stacking fault energy steel strain strength structure surface temperature tensile tensile stress tetrahedra thermal tion transformation twinning vacancies voids work-hardening X-ray yield stress zone