Mechanical Behavior of Materials |
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Page 64
... compression of an ideal gas , for which the potential energy is also independent of volume . This independence results from the absence of intermolecular interactions in an ideal gas owing to the large spacings between molecules . For a ...
... compression of an ideal gas , for which the potential energy is also independent of volume . This independence results from the absence of intermolecular interactions in an ideal gas owing to the large spacings between molecules . For a ...
Page 152
... compression axis . ( b ) During compres- sion the slip direction rotates away from the compression axis , while the slip plane normal rotates toward it . Even though the respective rotations are different for com- pression and tension ...
... compression axis . ( b ) During compres- sion the slip direction rotates away from the compression axis , while the slip plane normal rotates toward it . Even though the respective rotations are different for com- pression and tension ...
Page 727
... compression , 696 energy absorption in compression , 698-704 failure modes in compression , 693–695 deformation map for elastomeric foams , 696-696 densities , 688-690 endurance limit - fatigue threshold stress intensity relationship ...
... compression , 696 energy absorption in compression , 698-704 failure modes in compression , 693–695 deformation map for elastomeric foams , 696-696 densities , 688-690 endurance limit - fatigue threshold stress intensity relationship ...
Contents
Overview of Mechanical Behavior | 1 |
Toughening Mechanisms and the Physics of Fracture | 10 |
Elastic Behavior | 44 |
Copyright | |
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alloys applied stress behavior bonding brittle Burgers vector ceramics Chap CHAPTER Coble creep composite compression crack growth crack propagation crack tip craze creep fracture creep rate Crystalline Materials cubic curve cyclical decreases depends discussed dislocation density dislocation line dislocation motion displacement ductile ductile fracture edge dislocation embrittlement energy equation example fatigue fcc metals fiber Figure flow stress Fracture Mechanics fracture toughness glass grain boundaries hardening high-temperature increases initial length linear elastic loading low-temperature macroscopic martensite material's matrix MN/m² modulus nucleation obstacles particle phase plastic deformation plastic flow plastic strain polycrystalline polycrystals polymers precipitation Prob ratio region result Schematic screw dislocation SECTION shear stress shown in Fig single crystal slip direction slip plane slip systems solids steel strain rate strengthening stress-strain structure superplastic surface takes place TCRSS temperature tensile axis tensile strength tensile stress tion toughening transition viscoelastic volume fraction work-hardening yield strength