## Mechanical Behavior of Materials |

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Page 22

The abscissa of this diagram represents a tensile (or compressive) stress and the

ordinate represents a

the only principal stress in the case of a tensile test) is marked on the tensile ...

The abscissa of this diagram represents a tensile (or compressive) stress and the

ordinate represents a

**shear stress**. The diagram is laid out so that the stress a, (the only principal stress in the case of a tensile test) is marked on the tensile ...

Page 23

Here the principal stresses, a, and a2, are laid out on the tensile stress axis. Their

difference defines the diameter of the Mohr's circle. The

plane oriented at the angle 6 with respect to the ct, axis is equal to the radius of ...

Here the principal stresses, a, and a2, are laid out on the tensile stress axis. Their

difference defines the diameter of the Mohr's circle. The

**shear stress**acting on aplane oriented at the angle 6 with respect to the ct, axis is equal to the radius of ...

Page 276

To keep our analysis consistent with previous treatments of load transfer to

discontinuous fibers, we take P' = $ldf, where dfis the fiber diameter. The

analogous to ...

To keep our analysis consistent with previous treatments of load transfer to

discontinuous fibers, we take P' = $ldf, where dfis the fiber diameter. The

**shear****stress**-shear strain rate behavior of the matrix is described by an equationanalogous to ...

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### Contents

Overview of Mechanical Behavior l | 1 |

A The Tension Test B StrainRate Sensitivity C Yielding Under | 28 |

A Fracture Toughness B Tensile Fracture C Creep Fracture | 37 |

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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 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 plane slip systems solids solute atom 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