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2. Collaborations between Caltech ASC center and DP labs. LLNL AX Division
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1. Collaborations between Caltech’s ASC alliance center and the DP labs Dan Meiron - Caltech ASC Center
ASC PI Meeting
San Antonio, TX
Feb. 24, 2005
2. 2 Collaborations between Caltech ASC center and DP labs LLNL AX Division – collaboration on compressible turbulence and mixing (this talk)
LLNL AX Division – collaboration on the mixing transition in Rayleigh-Taylor flows (Dimotakis, Cook)
LLNL DTED – collaboration on solid-fluid interaction (Hoover, Meiron)
LLNL CMS – collaboration on multiscale modeling of spall (Ortiz, Becker)
LLNL CMS – collaboration on quasicontinuum approach (Bulatov, Ortiz)
LLNL – collaboration on MD simulation of R-M instability (Goddard, Zybin, Bringa)
LANL – collaboration on multiscale modeling of materials using phase field modeling (Koslowski, Ortiz)
LANL – collaboration on Ferroelectrics (Strachan, Goddard)
LANL – collaboration on subgrain structures and laminates (Beyerlein, Ortiz)
LANL - Simulations of Thermal Decomposition of Polydimethylsiloxane Polymer (Kober, Goddard)
LANL Validation of ReaxFF vs. ab initio MD by studying nitromethane thermal decomposition (Strachan, Goddard)
Sandia Materials – collaboration on electronic structure code Sequest (Goddard, Schulz)
Sandia - collaboration on AMR techniques (Ray, Steensland)
5. Phase-field dislocation dynamics
6. Phase-field dislocation dynamics
7. Phase-field dislocation dynamics
8. Phase-field dislocation dynamics
9. Equal Angular Channel Extrusion
12. 12 Current capability – Limitations Calculations so far have been based on cohesive elements/laws
Replace cohesive model by:
Porous plasticity and damage localization model (K. Weinberg, A. Mota and M. Ortiz, JCM, submitted).
Strain-localization elements (Yang, Mota and Ortiz, IJNME, to appear).
13. 13 Spall – Engineering model - Validation
14. 14 Spall – Engineering model – Assumptions Need estimates of:
Elastic energy, EoS
Plastic dissipation
Kinetic energy
Nucleation kinetics
Coarsening kinetics
…
15. Quasicontinuum 2 Dislocation Dynamics Computed shear stress as a function of the shear angle.
On the loading curve, ($\tau_l$,$\theta$), three main regimes,
separated by yield points, can be clearly discerned: i) stage I
corresponding to elastic loading, ii) stage II corresponding to primary
dislocation glide and Lomer-Cottrell junction formation, and iii)
stage III corresponding to secondary dislocation glide, cross-slip and stress
saturation. The recovery behavior of the material,
($\tau_u$,$\theta$), is gradual and accompanied by the
corresponding dislocation density reduction. The area encircled
by both curves represents the net plastic work.}
Incipient partial dislocation structures generated on the
planes of maximum RSS occurring at $45^\circ$ to the shear
direction at a shear angle and stress of $6.9^\circ$ and
$4.3$~GPa, respectively, corresponding to the first yield
point. Atoms belonging to a partial dislocation or a stacking
fault can be seen in red and orange, while atoms part of the
original void are shown in green/gray}
Dislocation structures corresponding at the onset of stage
III. Lomer-Cottrell locks forme by reaction of the initial
leading Shockley partials. The Lomer-Cottrell harden the
primary slip planes, which become inactive. Shear loops are
subsequently emitted on secondary slip planes driven by the
attendant stress rise.}
Final dislocation structures at the end of stage III of the
loading phase. The dominant features are large
$\small{\frac{1}{6}}\langle112\rangle$ partial dislocation
loops growing on $\{111\}$ planes. Other features, such as
jogs and cross-slipped sections, are also observed in the figure.
Computed shear stress as a function of the shear angle.
On the loading curve, ($\tau_l$,$\theta$), three main regimes,
separated by yield points, can be clearly discerned: i) stage I
corresponding to elastic loading, ii) stage II corresponding to primary
dislocation glide and Lomer-Cottrell junction formation, and iii)
stage III corresponding to secondary dislocation glide, cross-slip and stress
saturation. The recovery behavior of the material,
($\tau_u$,$\theta$), is gradual and accompanied by the
corresponding dislocation density reduction. The area encircled
by both curves represents the net plastic work.}
Incipient partial dislocation structures generated on the
planes of maximum RSS occurring at $45^\circ$ to the shear
direction at a shear angle and stress of $6.9^\circ$ and
$4.3$~GPa, respectively, corresponding to the first yield
point. Atoms belonging to a partial dislocation or a stacking
fault can be seen in red and orange, while atoms part of the
original void are shown in green/gray}
Dislocation structures corresponding at the onset of stage
III. Lomer-Cottrell locks forme by reaction of the initial
leading Shockley partials. The Lomer-Cottrell harden the
primary slip planes, which become inactive. Shear loops are
subsequently emitted on secondary slip planes driven by the
attendant stress rise.}
Final dislocation structures at the end of stage III of the
loading phase. The dominant features are large
$\small{\frac{1}{6}}\langle112\rangle$ partial dislocation
loops growing on $\{111\}$ planes. Other features, such as
jogs and cross-slipped sections, are also observed in the figure.
17. Large-scale atomistic simulation of shock instabilities in materials
