Your search keyword '"Large scale simulation"' showing total 2 results

1. GPU-accelerated molecular dynamics simulation for study of liquid crystalline flows

Author

Sunarso, Alfeus, Tsuji, Tomohiro, and Chono, Shigeomi

Subjects

*GRAPHICS processing units, *MOLECULAR dynamics, *SIMULATION methods & models, *LIQUID crystals, *ANISOTROPY, *ELECTRIC fields, *INTERMOLECULAR forces

Abstract

Abstract: We have developed a GPU-based molecular dynamics simulation for the study of flows of fluids with anisotropic molecules such as liquid crystals. An application of the simulation to the study of macroscopic flow (backflow) generation by molecular reorientation in a nematic liquid crystal under the application of an electric field is presented. The computations of intermolecular force and torque are parallelized on the GPU using the cell-list method, and an efficient algorithm to update the cell lists was proposed. Some important issues in the implementation of computations that involve a large number of arithmetic operations and data on the GPU that has limited high-speed memory resources are addressed extensively. Despite the relatively low GPU occupancy in the calculation of intermolecular force and torque, the computation on a recent GPU is about 50 times faster than that on a single core of a recent CPU, thus simulations involving a large number of molecules using a personal computer are possible. The GPU-based simulation should allow an extensive investigation of the molecular-level mechanisms underlying various macroscopic flow phenomena in fluids with anisotropic molecules. [Copyright &y& Elsevier]

Published

2010

2. A parallel algorithm for 3D dislocation dynamics

Author

Wang, Zhiqiang, Ghoniem, Nasr, Swaminarayan, Sriram, and LeSar, Richard

Subjects

*JOINT dislocations, *ABNORMALITIES in animals, *SIMULATION methods & models, *ELASTICITY

Abstract

Abstract: Dislocation dynamics (DD), a discrete dynamic simulation method in which dislocations are the fundamental entities, is a powerful tool for investigation of plasticity, deformation and fracture of materials at the micron length scale. However, severe computational difficulties arising from complex, long-range interactions between these curvilinear line defects limit the application of DD in the study of large-scale plastic deformation. We present here the development of a parallel algorithm for accelerated computer simulations of DD. By representing dislocations as a 3D set of dislocation particles, we show here that the problem of an interacting ensemble of dislocations can be converted to a problem of a particle ensemble, interacting with a long-range force field. A grid using binary space partitioning is constructed to keep track of node connectivity across domains. We demonstrate the computational efficiency of the parallel micro-plasticity code and discuss how O(N) methods map naturally onto the parallel data structure. Finally, we present results from applications of the parallel code to deformation in single crystal fcc metals. [Copyright &y& Elsevier]

Published

2006