PARADISCYL:Cylinder-Surface cross slip: Difference between revisions
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[[Image:Schematic_view.jpg|frameless|300px|right|Fig.2. ]] |
[[Image:Schematic_view.jpg|frameless|300px|right|Fig.2. ]] |
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If there is a screw dislocation in the BCC crystal in left figure, we can see that there are three possible slip planes(red, blue green planes in the figure). From the MD calculation we |
If there is a screw dislocation in the BCC crystal in left figure, we can see that there are three possible slip planes(red, blue green planes in the figure). From the MD calculation, we knew the image stress generate the force to move dislocations in the direction along which the length of dislocation would be shortened.Therefore, image force points downward for the front node, while it points upward for the back node(Figure 1). However, P-K force points in same direction both front node and back node. Taking the summation of these forces into account, the slip plane is selected as the one on which projected total force has maximum value. |
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For simplicity, we In the first test case, image stress of a straight edge dislocation is considered, as shown in the ''Figure 1'', where dislocation is offset(<math>x0</math>) from the center of the cylinder. We have two cases of <math>x0</math>=0.5<math>R</math> and 0.9<math>R</math>.Here, <math>R</math> is the radius of the cylinder. |
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|[[Image:Force_sum1.jpg|frameless|350px|caption]] |
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|align="center"|(b) |
|align="center"|(b) |
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|colspan="2" | Fig.1 (a) When the P-K force is dominant(blue plane is taken as a slip plane)(b) When the image force is dominant(green plane is taken as a slip plane) |
|colspan="2" | Fig.1 (a) When the P-K force is dominant(blue plane is taken as a slip plane for the front node, while red plane is selected for the back node)(b) When the image force is dominant(green plane is taken as a slip plane) |
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Since the image stress field of this configuration had been solved analytically[Eshelby, J.D., 1979],we compare the image force between the simulation result and analytic solution.The number of grids in circumferential direction is same as the one along the cylinder axis.To consider periodic images along the cylinder axis under PBC, analytical stress field of edge dislocation is implemented in the function of "AllSegmentStress_no_cell_test1".To use this function, modify '''makefile''' in ParaDiS/cylinder directory so that the following line is active. |
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DEFS += -D_CYL_TEST1 |
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[[Image:Relative error plot.jpg|frameless|400px|right|Fig.2. ]] |
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Using Method I,the relative error in the image force is computed from the image stress calcualtion. Right plot clearly show exponential decay of the relative error with increasing number of grids. The convergence is slower when the location of the edge dislocation is close to the surface. |
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In this mechanism, straight edge dislocation has two different slip planes(See Figure 1-(a)). |
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==Algorithm== |
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1. Searching for the surface node(node in Figure 2.(a)) |
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2. Find the neighbor node(nbr1 in Figure 2.(a)) |
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3. Check if the character of surface segment is similar to screw |
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<math> 1.0-\mathbf{b} \cdot \mathbf{ \xi}<= \epsilon</math> |
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, where <math>\epsilon</math> is a tolerance. |
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4. Given burgers vector, there are three possible slip planes. For example, if <math>\mathbf{b} = a[111]</math>, then possible slip planes are <math>\mathbf{n}_1 = [1\bar{1}1],\mathbf{n}_2 = [0\bar{1}1],\mathbf{n}_3 = [\bar{1}01]</math>(See figure 2(b)) |
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5. Compute projected forces on each plane. |
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<math>\mathbf{F}_{i} = \mathbf{F}_{total}-(\mathbf{F}_{total} \cdot \mathbf{n}_i)\mathbf{n}_i</math> |
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6. Based on the magnitudes of <math>\mathbf{F}_{i}</math>, choose slip plane of the surface dislocation segment. |
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|[[Image:cylinder_fig.jpg |frameless|300px|caption]] |
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|[[Image:slip_system.jpg |frameless|300px|caption]] |
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|align="center"|(a) |
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|align="center"|(b) |
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|colspan="2" | Fig.2 (a)Schematic (b) Slip system <math>\mathbf{b} = a[111],\mathbf{n}_1 = [1\bar{1}1],\mathbf{n}_2 = [0\bar{1}1],\mathbf{n}_3 = [\bar{1}01]</math>. |
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Latest revision as of 01:01, 8 December 2011
Surface cross slip
ill Ryu and Wei Cai
This tutorial describes how to implement cross slip mechanism from the cylinder surface. The theoretical background is published in Computing Image Stress in an Elastic Cylinder(Proceedings of the National Academy of Sciences, 105, 14304 (2008)http://micro.stanford.edu/~caiwei/papers/Weinberger08PNAS-bccpillar.pdf (PDF)])
How to select slip plane of the surface segments
To implement surface cross slip in cylinder code, we change the slip plane of the surface nodes with respect to the magnitude of the force on the surface nodes.To do that,dislocation character of the surface nodes should be screw-like.
If there is a screw dislocation in the BCC crystal in left figure, we can see that there are three possible slip planes(red, blue green planes in the figure). From the MD calculation, we knew the image stress generate the force to move dislocations in the direction along which the length of dislocation would be shortened.Therefore, image force points downward for the front node, while it points upward for the back node(Figure 1). However, P-K force points in same direction both front node and back node. Taking the summation of these forces into account, the slip plane is selected as the one on which projected total force has maximum value.