TY - GEN
T1 - Peta-scale phase-field simulation for dendritic solidification on the TSUBAME 2.0 supercomputer
AU - Shimokawabe, Takashi
AU - Aoki, Takayuki
AU - Takaki, Tomohiro
AU - Yamanaka, Akinori
AU - Nukada, Akira
AU - Endo, Toshio
AU - Maruyama, Naoya
AU - Matsuoka, Satoshi
PY - 2011
Y1 - 2011
N2 - The mechanical properties of metal materials largely depend on their intrinsic internal microstructures. To develop engineering materials with the expected properties, predicting patterns in solidified metals would be indispensable. The phase-field simulation is the most powerful method known to simulate the micro-scale dendritic growth during solidification in a binary alloy. To evaluate the realistic description of solidification, however, phase-field simulation requires computing a large number of complex nonlinear terms over a fine-grained grid. Due to such heavy computational demand, previous work on simulating three-dimensional solidification with phase-field methods was successful only in describing simple shapes. Our new simulation techniques achieved scales unprecedentedly large, sufficient for handling complex dendritic structures required in material science. Our simulations on the GPU-rich TSUBAME 2.0 supercomputer at the Tokyo Institute of Technology have demonstrated good weak scaling and achieved 1.017 PFlops in single precision for our largest configuration, using 4,000 GPUs along with 16,000 CPU cores.
AB - The mechanical properties of metal materials largely depend on their intrinsic internal microstructures. To develop engineering materials with the expected properties, predicting patterns in solidified metals would be indispensable. The phase-field simulation is the most powerful method known to simulate the micro-scale dendritic growth during solidification in a binary alloy. To evaluate the realistic description of solidification, however, phase-field simulation requires computing a large number of complex nonlinear terms over a fine-grained grid. Due to such heavy computational demand, previous work on simulating three-dimensional solidification with phase-field methods was successful only in describing simple shapes. Our new simulation techniques achieved scales unprecedentedly large, sufficient for handling complex dendritic structures required in material science. Our simulations on the GPU-rich TSUBAME 2.0 supercomputer at the Tokyo Institute of Technology have demonstrated good weak scaling and achieved 1.017 PFlops in single precision for our largest configuration, using 4,000 GPUs along with 16,000 CPU cores.
KW - Experimentation
KW - Performance
UR - http://www.scopus.com/inward/record.url?scp=83155190228&partnerID=8YFLogxK
U2 - 10.1145/2063384.2063388
DO - 10.1145/2063384.2063388
M3 - Conference contribution
AN - SCOPUS:83155190228
SN - 9781450307710
T3 - Proceedings of 2011 SC - International Conference for High Performance Computing, Networking, Storage and Analysis
BT - Proceedings of 2011 SC - International Conference for High Performance Computing, Networking, Storage and Analysis
T2 - 2011 International Conference for High Performance Computing, Networking, Storage and Analysis, SC11
Y2 - 12 November 2011 through 18 November 2011
ER -