## Mechanical Behavior of Materials |

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Page 277

6.27 (the asymptotic stress in this

creep rate is found by rearranging Eq. (6.45); e, = o; - Vfaf(t) VmKm i fm (6.51)

The stress oy(f) in Eq. (6.51) increases with time (Fig. 6.27) until the value of it is

given ...

6.27 (the asymptotic stress in this

**figure**is given by Eq. (6.50)). The compositecreep rate is found by rearranging Eq. (6.45); e, = o; - Vfaf(t) VmKm i fm (6.51)

The stress oy(f) in Eq. (6.51) increases with time (Fig. 6.27) until the value of it is

given ...

Page 533

1 1.6 and indirectly in Fig. 1 1 .7. However, the latter

rupture- fracture times are short; this results from the typically high strain rates

that accompany rupture fracture. The processes resulting in TCF5 have been

described ...

1 1.6 and indirectly in Fig. 1 1 .7. However, the latter

**figure**also shows thatrupture- fracture times are short; this results from the typically high strain rates

that accompany rupture fracture. The processes resulting in TCF5 have been

described ...

Page 592

CHAPTER 12 Fatigue of Engineering Materials IT. i Employ Eq. (12.4) ' Employ

Eq. (12.6) Endurance limit I Intrinsic I Fatigue | FAIL SAFE FATIGUE I A.r th

Extrinsic fatigue (a) Crack length

crack ...

CHAPTER 12 Fatigue of Engineering Materials IT. i Employ Eq. (12.4) ' Employ

Eq. (12.6) Endurance limit I Intrinsic I Fatigue | FAIL SAFE FATIGUE I A.r th

Extrinsic fatigue (a) Crack length

**Figure**12.21 (a) Allowable stress amplitude vs.crack ...

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### Contents

Overview of Mechanical Behavior l | 1 |

Toughening Mechanisms and the Physics of Fracture 454 | 10 |

Overview of Mechanical Behavior l | 18 |

Copyright | |

25 other sections not shown

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### Common terms and phrases

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 cubic curve cyclical decreases depends discussed dislocation density dislocation line dislocation motion displacement ductile ductile fracture edge dislocation embrittlement energy equation example fatigue fiber Figure flow stress Fracture Mechanics fracture toughness glass grain boundaries greater hardening high-temperature illustrated in Fig increases initial interaction length linear elastic loading low temperatures martensite material's matrix maximum microscopic 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 levels stress-strain structure superplastic surface takes place tensile axis tensile strength tensile stress tion toughening transition viscoelastic void growth volume fraction work-hardening yield strength