GPU-Accelerated Molecular Dynamics Simulation to Study Liquid Crystal Phase Transition Using Coarse-Grained Gay-Berne Anisotropic Potential

GPU-Accelerated Molecular Dynamics Simulation to Study Liquid Crystal Phase Transition Using Coarse-Grained Gay-Berne Anisotropic Potential

Gay-Berne (GB) potential is regarded as an accurate model in the simulation of anisotropic particles, especially for liquid crystal (LC) mesogens. However, its computational complexity leads to an extremely time-consuming process for large systems. Here, we developed a GPU-accelerated molecular dyna...

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Bibliographic Details
Published in:PloS one Vol. 11; no. 3; p. e0151704
Main Authors: Chen, Wenduo, Zhu, Youliang, Cui, Fengchao, Liu, Lunyang, Sun, Zhaoyan, Chen, Jizhong, Li, Yunqi
Format: Journal Article
Language:English
Published: United States Public Library of Science 17-03-2016
Public Library of Science (PLoS)
Subjects:
Algorithms
Analysis
Anisotropy
Artificial rubber
Behavior
Biology and Life Sciences
Chains (polymeric)
Chemistry
Coarsening
Computer applications
Computer simulation
Laboratories
Liquid crystal polymers
Liquid crystals
Liquid Crystals - chemistry
Melts
Models, Theoretical
Molecular dynamics
Molecular Dynamics Simulation
Nematic
Packaging
Phase Transition
Phase transitions
Phase transitions (Physics)
Physical Sciences
Physics
Polyesters
Polymerization
Polymers
Research and Analysis Methods
Science
Simulation
Iran
China
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Summary:Gay-Berne (GB) potential is regarded as an accurate model in the simulation of anisotropic particles, especially for liquid crystal (LC) mesogens. However, its computational complexity leads to an extremely time-consuming process for large systems. Here, we developed a GPU-accelerated molecular dynamics (MD) simulation with coarse-grained GB potential implemented in GALAMOST package to investigate the LC phase transitions for mesogens in small molecules, main-chain or side-chain polymers. For identical mesogens in three different molecules, on cooling from fully isotropic melts, the small molecules form a single-domain smectic-B phase, while the main-chain LC polymers prefer a single-domain nematic phase as a result of connective restraints in neighboring mesogens. The phase transition of side-chain LC polymers undergoes a two-step process: nucleation of nematic islands and formation of multi-domain nematic texture. The particular behavior originates in the fact that the rotational orientation of the mesogenes is hindered by the polymer backbones. Both the global distribution and the local orientation of mesogens are critical for the phase transition of anisotropic particles. Furthermore, compared with the MD simulation in LAMMPS, our GPU-accelerated code is about 4 times faster than the GPU version of LAMMPS and at least 200 times faster than the CPU version of LAMMPS. This study clearly shows that GPU-accelerated MD simulation with GB potential in GALAMOST can efficiently handle systems with anisotropic particles and interactions, and accurately explore phase differences originated from molecular structures.
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Competing Interests: The authors have declared that no competing interests exist.
Conceived and designed the experiments: WC YL. Performed the experiments: WC YZ FC. Analyzed the data: WC LL YL. Contributed reagents/materials/analysis tools: YZ FC ZS. Wrote the paper: WC JC ZS YL.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0151704