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Summary of Martensite Formation Simulations

Summary of Martensite Formation Simulations. June 27, 2012. Simulation Setup 1: Uniaxial Compression. Simulations performed with large box: 22 x 22 x 11 nm (432,000 atoms) – orientation X||[100], Y||[010] Prismatic box (shearing allowed)

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Summary of Martensite Formation Simulations

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  1. Summary of Martensite Formation Simulations June 27, 2012

  2. Simulation Setup 1: Uniaxial Compression • Simulations performed with large box: 22 x 22 x 11 nm (432,000 atoms) – orientation X||[100], Y||[010] • Prismatic box (shearing allowed) • Perform NPT simulations controlling pressure along the Y and Z directions (and XY,YZ,XZ) to be zero (temperature fixed to be 1 K) • Compress parallel to the X-direction using “fix deform” – scale X length by 0.9 by the end of simulation • Run MD simulations for 100,000 timesteps This mimics performing a compression test parallel to [100] with zero stress in the other two directions and the possibility of the box to shear – however, the length of the box in the X-direction (Lx) is controlled throughout the simulation, Ly, Lzand shears can change in response to the formation of BCC phase but the surface normal to Lx must remain flat.

  3. Simulation Setup 1: Uniaxial Compression Y 22 nm 11 nm Z X Deformation controlled in X direction (fix deform) Stresses controlled in other directions (npt – zero stresses) 22 nm

  4. Results 1: Stress-Strain This is the stress-strain response in the x-direction – i.e. the direction along with the compressive strain is being applied. Stresses along all other directions are zero (or very close to zero) throughout the simulation.

  5. Results 1: Stress-Strain Focus on the stress-strain response of the austenite before transformation – the response is perfectly quadratic – in other words the elastic moduli tend to decrease linearly with strain

  6. Results 1: Softening of Elastic Constants Indeed, you see this perfectly for C11, C12 and for C11-C12 (plotted here) The transformation does not occur until after C11-C12 < 0. Here I show this modulus (C11-C12) just up to the point where the transformation occurs. I think that this is due to the fact that we constrain the displacement in the x-direction and allow the stress to adjust in this direction.

  7. Results 1: Softening of Elastic Constants Also a consequence of all of this is that the elastic energy varies as a perfect cubic function of the strain – notice that the total energy continues to increase monotonically up to almost 5% strain where the FCC crystal becomes unstable. So, even though the modulus becomes negative the system energy continues to go up with continued deformation.

  8. Results 1: Softening of Elastic Constants …here is the total energy as a function of the imposed strain parallel to the [100] direction…

  9. Results 1: Heat Released The transformation occurs with the release of latent heat – this causes the temperature of the simulation box to go up as can be seen here. The temperature rise is significant but I don’t think that this significantly affects the results.

  10. Results 1: Transformation ex = -5.2% 53% FCC ex = -5.1% 93% FCC ex = -5% 100% FCC ex = -5.4% 23% FCC ex = -5.5% 0% FCC Coord. Color 7 purple 8 LightSteelBlue 9 magenta 10 LimeGreen 11 MediumVioletRed 12 LightGoldenrod Rcut = 2.71017 A

  11. Results 1: Crystallography Y ex = -5% 100% FCC X ex = -5.4% ex = -5.2% Images showing the change in structure of box with continued strain. The outline of the original box is shown overlaid on the final box showing the shear and the strong decrease in height in the y-direction ex = -5.6% ex = -5.8% ex = -6.0%

  12. Results 1: Crystallography Y X This figure shows sn early stage of the transformation – showing only the BCC coordinated atoms. One can see a regular pattern – I was expecting this to be on {110} planes but apparently not – if you loot at the angles, one can see that the bands make an angle of ~52o with the horizontal 45o 52o

  13. Results 1: Crystallography The morphology of these bands, however, is quite complex – made up of what appears to be different variants – i.e. the bands are neither continuous nor are they actually just single bands. They are made up of many smaller clusters having different crystallographic orientations

  14. Results 1: Crystallography Y X Finally, by the end of the transformation two orientations end up remaining – these are twinned with respect to on another. Can also see the significant shear of the box.

  15. Results 1: Crystallography Y The Z-direction (out of the board) is <110> in both orientations. Relative to the original . X [100] [110] [100] [-111] [-111] [110]

  16. Results 1: Crystallography [010]FCC [110]FCC [100]FCC [111]BCC [112]BCC Orientation Relationship [110]FCC||[112]BCC [001]FCC || [-110]BCC PitschOrientation Relationship Same as what I found in my 2008 Acta Paper!

  17. Summary • Get transformation at ~5% strain – once rate of energy storage starts to decrease • Formation of many small variants (different orientations) giving away to two twinned variants • Appears that Pitsch orientation relationship exists between original FCC and product BCC

  18. Results 1: Crystallography Ran a second simulation under the same basic conditions but with different initial conditions and got a different set of two variants (not surprising). Can see here colours according to the strain JXZ

  19. Z Results 1: Crystallography X Can see the shearing in this plane – interesting to look at the strains in the two variants: Variant 2 Variant 1 JXX = 1.123 JYY = 1.090 JZZ = 0.768 JXY = 0.023 JYX = 0.005 JXZ = -0.199 JZX = 0.112 JYZ = 0.023 JZY = -0.012 JXX = 0.786 JYY = 1.100 JZZ = 1.060 JXY = -0.012 JYX = 0.022 JXZ = 0.141 JZX = -0.172 JYZ = -0.002 JZY = -0.009

  20. Results 1: Crystallography Variant 1 Variant 2 Can we check and see if these strains are consistent with the expected orientation relationship? Coordinate system for J is the FCC system. JXX = 1.123 JYY = 1.090 JZZ = 0.768 JXY = 0.023 JYX = 0.005 JXZ = -0.199 JZX = 0.112 JYZ = 0.023 JZY = -0.012 JXX = 0.786 JYY = 1.100 JZZ = 1.060 JXY = -0.012 JYX = 0.022 JXZ = 0.141 JZX = -0.172 JYZ = -0.002 JZY = -0.009 Sorry, have changed nomenclature here to follow Bhadeshia – F = deformation gradient Start with the FCC  BCC transformation via Bain: To make Pitsch from Bain, rotate by 10.26oabout the [100]g direction: Combining the rotation and Bain strain gives the deformation gradient: Compare this with the variants above! Can then calculate the orientation relation (to confirm this gives Pitsch) using (See Bhadeshia) This is Pitsch!

  21. Look at the path – do atoms first undergo Bain strain then rotation or is it all at once – appears to be all at once – see change in both Jxx and Jzxsimulataneously Red Square Red Circle Blue Square Blue Circle Z X

  22. Results 1: Crystallography Variant 1 Variant 2 JXX = 0.786 JYY = 1.100 JZZ = 1.060 JXY = -0.012 JYX = 0.022 JXZ = 0.141 JZX = -0.172 JYZ = -0.002 JZY = -0.009 JXX = 1.123 JYY = 1.090 JZZ = 0.768 JXY = 0.023 JYX = 0.005 JXZ = -0.199 JZX = 0.112 JYZ = 0.023 JZY = -0.012 Notice that the Pitsch OR would suggest a rotation of the box by ~10o about the y-direction due to the transformation – here we do see a rotation but only by ~ 3o This smaller rotation is due to the fact that the two variants cause equal and opposite rotations about the y-direction. However, a small rotation remains because there is slightly more red variant than blue variant

  23. Summary • Can show that the local strains found at individual atoms are consistent with that expected from the Pitsch orientation relationship • Seems that the transformation from FCC  BCC with Pitsch OR follows a continuous path – don’t have a first Bain strain followed by rotation – both processes occur simultaneously

  24. Simulation 2: Control Deformation Purely by Stress • Changed the simulation to perform NPT with zero stress in all directions except the X-direction • In the X-direction the stress was increased from 0 to – 2GPa over 100,000 time steps – previously the strain (deformation) was controlled in the X-direction and the stress was free to change in this direction • Box size and shape and boundary conditions were the same as for the previous simulations.

  25. Here are the stress (in the X-direction) plotted against strain in the X-direction (top) and Y-direction (right) up to the point of transformation. One can see again that the potential gives a perfect quadratic fit to the stress-strain response. However, comparing these plots to the plot on figure 5 one can see that the transformation commences just at the point where the stress is maximum – now that there is no constraint on the strain in any direction the transformation can occur when the Born condition is satisfied…

  26. An easy way to see how rapid the transformation is in this case is to plot the energy versus time step – the inset shows that the transformation takes place over less than 100 timesteps – this is on the order of picoseconds.

  27. Interestingly, if one plots the energy versus the axial strain one can see the full energy profile – however, compared to the figure on slide 7 the axial strain is uncontrolled here – thus the barrier is able to be overcome since we hold the stress fixed in the x-direction (the energy is going up while the stress is fixed).

  28. ex = -0.0345 To see the condition when the transformation actually occurs it is interesting to plot the axial strain versus the time step – here you can see that the strain just prior to instability is ~ 3.45%...

  29. ex = -0.0345 ... This corresponds exactly to the point where the Born criterion is fulfilled – C11-C12 = 0 This helps to confirm that for a box under stress control, free to deform as it wishes, the transformation will commence once the Born condition is met

  30. In this case the transformation occurs very rapidly – in < 200 timesteps (I only output results every 200 timesteps) the structure completely transforms, uniformly from FCC (yellow) to BCC (silver)

  31. Y X [011]BCC [100]BCC [010]FCC [100]FCC You can also clearly see the change in box-size on transformation The orientation relationship in this case is Bain

  32. Summary 2 • When the deformation is controlled purely by stress it occurs at the Born instability condition C11-C12 = 0. This confirms that the calculations performed by Loic using molecular statics were probably over-constrained in some way. • In this case the transformation occurs nearly instantaneously (much faster than when strain is controlled) • Orientation relationship is Bain – this mirrors what we did with Loic last summer (only using molecular statics)

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