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Page 156
... stress , rather than force per bond . While a force can be described by giving its magnitude and direction , the descrip- tion of a stress requires four quantities : the magnitude and ... Shear Strength of Deformable Single Crystals,
... stress , rather than force per bond . While a force can be described by giving its magnitude and direction , the descrip- tion of a stress requires four quantities : the magnitude and ... Shear Strength of Deformable Single Crystals,
Page 157
... shear stress in the slip direction on the slip plane and σ is the applied normal stress . Thus , a normal stress applied to a single crystal causes a shear stress on the slip plane along the slip direction . This component of stress ...
... shear stress in the slip direction on the slip plane and σ is the applied normal stress . Thus , a normal stress applied to a single crystal causes a shear stress on the slip plane along the slip direction . This component of stress ...
Page 202
James P. Schaffer. Shear strain Y = dy / dx Shear stress T = F / A -dy Solid dx dx ( a ) Shear stress Shear strain rate d ( dy / dt ) dx dy d ( dy ) dt t = F / A = dt Liquid ( b ) Figure 6.3-1 A comparison of the response of solids and ...
James P. Schaffer. Shear strain Y = dy / dx Shear stress T = F / A -dy Solid dx dx ( a ) Shear stress Shear strain rate d ( dy / dt ) dx dy d ( dy ) dt t = F / A = dt Liquid ( b ) Figure 6.3-1 A comparison of the response of solids and ...
Contents
Materials Science and Engineering | 2 |
CHAPTER | 4 |
CHAPTER | 12 |
Copyright | |
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alloy aluminum anion applications atoms band band gap BCC structure bond-energy curve brittle Calculate carbon cation ceramics chain Chapter charge carriers classes of materials close-packed coefficient component composition compound conductivity containing corrosion covalent bonds crack crystal structure crystalline cubic decreases defects density determined dielectric diffusion dipole direction discussed dislocation ductility elastic elastic modulus electrical electronegative energy engineering Equation equilibrium eutectic eutectoid Example Problem fatigue ferromagnetic fibers fraction fracture glass glass transition temperature grain boundaries heat impurity increases interface interstitial ions lattice liquid load magnetic martensite matrix mechanical melting metal microstructure modulus molecules nucleation occurs oxide pearlite peritectic phase diagram plane polyethylene polymers primary bonds properties quench ratio reaction region resistance result schematic secondary bonds semiconductors shown in Figure shows silicon SiO2 solid solution steel strain strength stress surface tensile tetrahedral transformation unit cell vacancies valence band