Structural Defects Mechanical Properties of Solids Lecture 3.0 Structural Defects Mechanical Properties of Solids
Defects in Crystal Structure Vacancy, Interstitial, Impurity Schottky Defect Frenkel Defect Dislocations – edge dislocation, line, screw Grain Boundary
Substitutional Impurities Interstitial Impurities
Self Interstitial Vacancy Xv~ exp(-Hv/kBT)
Vacancy Equilibrium Xv~ exp(-Hv/kBT)
Defect Equilibrium Sc= kBln gc(E) Sb= kBln Wb Entropy Ss= kBln Ws dFc = dE-TdSc-TdSs, the change in free energy dFc ~ 6 nearest neighbour bond energies (since break on average 1/2 the bonds in the surface) Wb=(N+n)!/(N!n!) ~(N+n+1)/(n+1) ~(N+n)/n (If one vacancy added) dSb=kBln((N+n)/n) For large crystals dSs<<dSb \ \n ~ N exp –dFc/kBT
Ionic Crystals Shottky Defect Frenkel Defect
Edge Dislocation
Grain Boundaries
Mechanical Properties of Solids Elastic deformation reversible Young’s Modulus Shear Modulus Bulk Modulus Plastic Deformation irreversible change in shape of grains Rupture/Fracture
Modulii Shear Young’s Bulk
Mechanical Properties Stress, xx= Fxx/A Shear Stress, xy= Fxy/A Compression Yield Stress yield ~Y/10 yield~G/6 (theory-all atoms to move together) Strain, =x/xo Shear Strain, =y/xo Volume Strain = V/Vo Brittle Fracture stress leads to crack stress concentration at crack tip =2(l/r) Vcrack= Vsound
Effect of Structure on Mechanical Properties Elasticity Plastic Deformation Fracture
Elastic Deformation Young’s Modulus Y(or E)= (F/A)/(l/lo) Shear Modulus G=/= Y/(2(1+)) Bulk Modulus K=-P/(V/Vo) K=Y/(3(1-2)) Pulling on a wire decreases its diameter l/lo= -l/Ro Poisson’s Ratio, 0.5 (liquid case=0.5)
Microscopic Elastic Deformation Interatomic Forces FT =Tensile Force FC=Compressive Force Note F=-d(Energy)/dr
Plastic Deformation Single Crystal by slip on slip planes Shear Stress
Deformation of Whiskers Without Defects Rupture With Defects generated by high stress
Dislocation Motion due to Shear
Slip Systems in Metals
Plastic Deformation Poly Crystals Ao by grain boundaries by slip on slip planes Engineering Stress, Ao True Stress, Ai Ai
Movement at Edge Dislocation Slip Plane is the plane on which the dislocation glides Slip plane is defined by BV and I
Plastic Deformation -Polycrystalline sample Many slip planes large amount of slip (elongation) Strain hardening Increased difficulty of dislocation motion due to dislocation density Shear Stress to Maintain plastic flow, =o+Gb dislocation density, Strain Hardening
Strain Hardening/Work Hardening Dislocation Movement forms dislocation loops New dislocations created by dislocation movement Critical shear stress that will activate a dislocation source c~2Gb/l G=Shear Modulus b=Burgers Vector l=length of dislocation segment
Depends on Grain Size
Burger’s Vector- Dislocations are characterised by their Burger's vectors. These represent the 'failure closure' in a Burger's circuit in imperfect (top) and perfect (bottom) crystal. BV Perpendicular to Dislocation BV parallel to Dislocation
Solution Hardening (Alloying) Solid Solutions Solute atoms segregate to dislocations = reduces dislocation mobility higher required to move dislocation Solute Properties larger cation size=large lattice strain large effective elastic modulus, Y Multi-phase alloys - Volume fraction rule
Precipitation Hardening Fine dispersion of heterogeneity impede dislocation motion c~2Gb/ is the distance between particles Particle Properties very small and well dispersed Hard particles/ soft metal matrix Methods to Produce Oxidation of a metal Add Fibers - Fiber Composites
Cracking vs Plastic Deformation Brittle Poor dislocation motion stress needed to initiate a crack is low Ionic Solids disrupt charges Covalent Solids disrupt bonds Amorphous solids no dislocations Ductile good dislocation motion stress needed to initiate slip is low Metals electrons free to move Depends on T and P ductile at high T (and P)