Deformation and Fracture Mechanics of Engineering MaterialsUpdated to reflect recent developments in our understanding of deformation and fracture processes in structural materials. This completely revised reference includes new sections on isostress analysis, modulus of rupture, creep fracture micromechanicsms, and many more. |
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Page 63
... depends on the dislocation width , which is dependent on atomic structure and the nature of the atomic bonding forces . For example , when the bonding forces are spherical in distribution and act along the line of centers between atoms ...
... depends on the dislocation width , which is dependent on atomic structure and the nature of the atomic bonding forces . For example , when the bonding forces are spherical in distribution and act along the line of centers between atoms ...
Page 139
... depends on four major factors : the volume fraction , distribution , the nature of the precipitate , and the nature of the interphase boundary . Surely , were all things to remain constant , the resistance to dislocation motion through ...
... depends on four major factors : the volume fraction , distribution , the nature of the precipitate , and the nature of the interphase boundary . Surely , were all things to remain constant , the resistance to dislocation motion through ...
Page 267
... depends on inherent measurement errors ( including those resulting from variations in specimen alignment and test environment ) and inherent property variations of the material . For purposes of this discussion , we will consider only ...
... depends on inherent measurement errors ( including those resulting from variations in specimen alignment and test environment ) and inherent property variations of the material . For purposes of this discussion , we will consider only ...
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Common terms and phrases
addition alloy aluminum alloy applied stress associated ASTM atoms behavior brittle ceramics Chapter Charpy component composite crack extension crack growth crack length crack tip craze creep rate crystal curve cyclic decrease depends determined dislocation ductility elastic embrittlement engineering example factor failure fiber FIGURE flaw fracture mechanics fracture surface fracture toughness given grain boundaries hardening hydrogen increasing initial KIEAC lattice load maraging steels martensite material material's matrix Metals Park microstructure microvoid modulus notch Note occur oriented parameter particles phase plane plane-strain plastic deformation plastic zone plate polymer polymeric region relative Reprinted with permission result rupture sample screw dislocation Section shear stress shown in Fig solid solution specimen stacking fault energy steel alloys strain rate stress concentration stress field stress intensity stress level stress-strain stress-strain curve superalloys tensile stress test temperature thermal thickness toughening Trans transition temperature twinning values yield strength