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Dependence of Grain Boundary Mobility on Boundary Plane

Dependence of Grain Boundary Mobility on Boundary Plane. Hao Zhang 1 , Mikhail Mendelev 1,2 and David Srolovitz 1. 1 PRISM, Princeton University 2 Ames Laboratory. Challenges.

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Dependence of Grain Boundary Mobility on Boundary Plane

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  1. Dependence of Grain Boundary Mobility on Boundary Plane Hao Zhang1, Mikhail Mendelev1,2 and David Srolovitz1 1PRISM, Princeton University 2Ames Laboratory

  2. Challenges • Neither curvature driven boundary migration experiments nor simulations yield the fundamental kinetic properties for grain boundary migration • ,M* is the product of the mobility and grain boundary stiffness • Reduced mobility is averaged over all possible inclinations • The migration of a flat boundary is easier to analyze, but has several limitations • Can yield grain boundary mobility dependence on inclination • Is the variation of grain boundary mobility correlated with other boundary properties, such as grain boundary energy and self-diffusivity?

  3. Free Surface 11 22 33 q Grain 2 22 11 33 Grain Boundary Z Grain 1 X Y Free Surface Elastically-Driven Migration of a Flat Boundary • Use elastic driving force • even cubic crystals are elastically anisotropic – equal strain  different strain energy • driving force for boundary migration: difference in strain energy density between two grains • Applied strain • constant biaxial strain in x and y • free surface normal to z  iz = 0 • Driving Force based on linear Elasticity S5 (001) tilt boundary

  4. Grain1 Grain2 Measured Driving Force • Typical strains • 1-2%, out of linear region • Implies driving force of form: • Measuring driving force • Apply strain εxx=εyy=ε0and σiz= 0 to perfect crystals, measure stress vs. strain and integrate to get the strain contribution to free energy • Includes non-linear contributions to elastic energy • Fit stress: • Driving force

  5. v/p p Determination of Mobility • Determine mobility by extrapolation to zero driving force • Tension (compression) data approaches from above (below)

  6. a a Symmetric boundary Asymmetric boundary a = 14.04º Asymmetric boundary a = 26.57º Simulation / Bicrystal Geometry [010] S5 36.87º

  7. Initial Simulation Cell for Different Inclinations

  8. Mobility vs. Inclination • No mobility data available at a=0, 45º; zero biaxial strain driving force • Mobilities vary by a factor of 4 over the range of inclinations studied at lowest temperature • Variation decreases when temperature ↑ (from ~4 to ~2) • Minima in mobility occur where one of the boundary planes has low Miller indices

  9. Activation Energy vs. Inclination • The variation of activation energy for grain boundary migration over the inclination region we studied is significant • The variation of mobility becomes weaker than expected on the basis of activation energy because of the compensation effect • Activation energy for the symmetric boundary is unknown

  10. Diffusivity vs. Inclination • Diffusivity shows more anisotropic at low temperature than at high temperature • Most of local minimum corresponds to one of the grains normal with low Miller indices • The a=0º has a change from minimum to maximum

  11. Activation Energy and Compensation Effect • The activation energy all lie between 0.5 to 0.6 eV, except for the a=0º symmetric boundary(1.1 eV) • Compensation effect weaken the diffusivity variation based upon the activation energy for self-diffusion

  12. Mobility, Self-diffusion and Energy • At low temperature, self-diffusion and grain boundary energy have similar trend, i.e. change from minimum to maximum, but mobility has opposite trend. • Mobility, self-diffusion coefficient and grain boundary energy shows local minimum at special inclination (one of the plane normal is low Miller indices) • There exists correlation between those three quantities in the inclination range of 18º to 45º.

  13. Conclusion • Used stress driven GB motion to determine grain boundary mobility as a function of q, a and T • Mobility is a strong function of inclination and temperature • Grain boundary self-diffusion is sensitive to inclinations, i.e. grain boundary structure • Minima in boundary mobility, self-diffusion coefficient and grain boundary energy occurs where at least one boundary plane is a low index plane • In the inclination range from 18º to 45º, there is a strong correlation between grain boundary diffusivity, energy and mobility

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