Coherency strain energy as a driving force for liquid grooving at grain boundaries

AbstractIn situ observations of CIGM in CaCO3 bicrystals with a SrCO3 solute source were made. The change in boundary orientation and migration rate were compared with solute concentration. The liquid film model for coherency strain Induced migration was generalized to any non-cubic system and applied to CaCO3-SrCO3. The coherent layer was modeled as a thin film on an infinite half-space. The strain energy was found from solution of the Hooke's law expressions transformed to the appropriate coordinate system. For triclinic or monoclinic films the strain tensor was found by an eigenvector decomposition of the transformation matrix that defined the lattice parameter change with composition. High anisotropy of Vegard's law constants for CaCO3-SrCO3 caused (111) to have the lowest coherency strain per unit solute. Surfaces perpendicular to (111) in coherent equilibria were predicted to have half the solute concentration and three times the migration driving force of those perpendicular to (111). However, no correlation between solute concentration and boundary orientation was observed. Ambiguous and contradictory evidence for a relationship between solute concentration, boundary orientation, and migration rate was found. The self-stress state of a grain boundary in a solute diffusion field may be better modelled as hydrostatic rather than plane stress. Hydrostatic compression may interact with the boundary excess volume and cause a PV driving force for migration. Predictions based on coherent equilibrium at a surface have not been tested for that geometry in calcite; they should be tested before they are applied to grain boundaries.

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Is Coherency Strain Energy the Driving Force for Diffusion Induced Grain Boundary Migration? / Ist die Kohärenzspannungsenergie die Triebkraft der diffusionsinduzierten Korngrenzenwanderung?

International Journal of Materials Research (formerly Zeitschrift fuer Metallkunde) ◽

10.1515/ijmr-1992-830812 ◽

1992 ◽

Vol 83 (8) ◽

pp. 633-637

Author(s):

Chien-Yung Ma ◽

Werner Laub ◽

Raymond A. Fournelle ◽

Wolfgang Gust ◽

Bruno Predel

Keyword(s):

Grain Boundary ◽

Driving Force ◽

Strain Energy ◽

Boundary Migration ◽

Coherency Strain ◽

Grain Boundary Migration

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Effects of Heat Treatment Condition on the Microstructure Evolution of Inconel 690

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.297-300.458 ◽

2005 ◽

Vol 297-300 ◽

pp. 458-462

Author(s):

Jung A. Lee ◽

Joon Hyung Lee ◽

Jeong Joo Kim ◽

Young Suck Chai

Keyword(s):

Heat Treatment ◽

Grain Boundary ◽

Grain Boundaries ◽

Driving Force ◽

Strain Energy ◽

Treatment Condition ◽

Heat Treatment Condition ◽

Depletion Zone ◽

Inconel 690 ◽

Discontinuous Coarsening

The effect of heat treatment on the morphologies of precipitates and grain boundaries of Inconel 690 alloy was studied. When the specimens were slowly cooled from the solutionizing temperature, typical discontinuous coarsening of Cr-rich carbides in grain boundaries was observed. As the cooling rate decreased, Cr-rich carbides grew and wider Cr depletion zone was created between the carbide precipitates, which resulted in wavy grain boundaries. The driving force of the wavy grain boundary was explained by the coherent strain energy.

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Coherency strain energy as a driving force for discontinuous ordering

Scripta Materialia ◽

10.1016/s1359-6462(97)00121-8 ◽

1997 ◽

Vol 37 (3) ◽

pp. 245-251 ◽

Cited By ~ 3

Author(s):

E. Rabkin ◽

V. Semenov ◽

W. Gust

Keyword(s):

Driving Force ◽

Strain Energy ◽

Coherency Strain

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The nucleation of cavities at grain boundaries

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100126299 ◽

1987 ◽

Vol 45 ◽

pp. 288-291

Author(s):

P. J. Goodhew

Keyword(s):

Surface Tension ◽

Surface Energy ◽

Grain Boundaries ◽

Radiation Damage ◽

Impurity Concentration ◽

Driving Force ◽

Nucleation And Growth ◽

Phase Boundaries ◽

Cavity Nucleation ◽

Spherical Bubble

Cavity nucleation and growth at grain and phase boundaries is of concern because it can lead to failure during creep and can lead to embrittlement as a result of radiation damage. Two major types of cavity are usually distinguished: The term bubble is applied to a cavity which contains gas at a pressure which is at least sufficient to support the surface tension (2g/r for a spherical bubble of radius r and surface energy g). The term void is generally applied to any cavity which contains less gas than this, but is not necessarily empty of gas. A void would therefore tend to shrink in the absence of any imposed driving force for growth, whereas a bubble would be stable or would tend to grow. It is widely considered that cavity nucleation always requires the presence of one or more gas atoms. However since it is extremely difficult to prepare experimental materials with a gas impurity concentration lower than their eventual cavity concentration there is little to be gained by debating this point.

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Crack Driving Force in Anisotropic Media due to Non-Elastic Deformation

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.261-263.75 ◽

2004 ◽

Vol 261-263 ◽

pp. 75-80

Author(s):

G.H. Nie ◽

H. Xu

Keyword(s):

Elastic Deformation ◽

Driving Force ◽

Strain Energy ◽

Elastic Stress ◽

Complex Function ◽

Crack Driving Force ◽

Special Cases ◽

Degree Of Anisotropy ◽

Minimum Strain Energy ◽

Orthotropic Media

In this paper elastic stress field in an elliptic inhomogeneity embedded in orthotropic media due to non-elastic deformation is determined by the complex function method and the principle of minimum strain energy. Two complex parameters are expressed in a general form, which covers all characterizations of the degree of anisotropy for any ideal orthotropic elastic body. The stress acting on the long side of ellipse can be considered as a crack driving force and applied in failure and fatigue analysis of composites. For some special cases, the resulting solutions will reduce to the known results.

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Introduction of low strain energy GdAlO3 grain boundaries into directionally solidified Al2O3/GdAlO3 eutectics

Acta Materialia ◽

10.1016/j.actamat.2021.117355 ◽

2021 ◽

pp. 117355

Author(s):

Xu Wang ◽

Wen Zhang ◽

Yujie Zhong ◽

Luchao Sun ◽

Qiaodan Hu ◽

...

Keyword(s):

Grain Boundaries ◽

Strain Energy ◽

Directionally Solidified

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Finite Element Modeling of Grain Aspect Ratio and Strain Energy Density in a Textured Copper Thin Film

MRS Proceedings ◽

10.1557/proc-436-411 ◽

1996 ◽

Vol 436 ◽

Cited By ~ 1

Author(s):

R. P. Vinci ◽

J. C. Bravman

Keyword(s):

Finite Element ◽

Energy Density ◽

Aspect Ratio ◽

Finite Element Modeling ◽

Strain Energy Density ◽

Driving Force ◽

Strain Energy ◽

Interface Energy ◽

Element Modeling ◽

Grain Aspect Ratio

AbstractWe have modeled the effects of grain aspect ratio on strain energy density in (100)-oriented grains in a (111)-textured Cu film on a Si substrate. Minimization of surface energy, interface energy, and strain energy density (SED) drives preferential growth of grains of certain crystallographic orientations in thin films. Under conditions in which the SED driving force exceeds the surface- and interface-energy driving forces, Cu films develop abnormally large (100) oriented grains during annealing. In the elastic regime the SED differences between the (100) grains and the film average arise from elastic anisotropy. Previous analyses indicate that several factors (e.g. elimination of grain boundaries during grain growth) may alter the magnitude of the SED driving force. We demonstrate, using finite element modeling of a single columnar (100) grain in a (111) film, that changes in grain aspect ratio can significantly affect the SED driving force. A minimum SED driving force is found for (100) Cu grains with diameters on the order of the film thickness. In the absence of other stagnation mechanisms, such behavior could cause small grains to grow abnormally and then stagnate while large grains continue to grow. This would lead to a bimodal grain size distribution in the (100) grains preferred by the SED minimization.

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