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Critical anomaly and finite size scaling of the self-diffusion coefficient for Lennard Jones fluids by non-equilibrium molecular dynamic simulation 被引量:4

Critical anomaly and finite size scaling of the self-diffusion coefficient for Lennard Jones fluids by non-equilibrium molecular dynamic simulation
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摘要 We use non-equilibrium molecular dynamics simulations to calculate the self-diffusion coefficient, D, of a Lennard Jones fluid over a wide density and temperature range. The change in self-diffusion coefficient with temperature decreases by increasing density. For density ρ* = ρσ3 = 0.84 we observe a peak at the value of the self-diffusion coefficient and the critical temperature T* = kT/ε = 1.25. The value of the self-diffusion coefficient strongly depends on system size. The data of the self-diffusion coefficient are fitted to a simple analytic relation based on hydrodynamic arguments. This correction scales as N-α, where α is an adjustable parameter and N is the number of particles. It is observed that the values of a 〈 1 provide quite a good correction to the simulation data. The system size dependence is very strong for lower densities, but it is not as strong for higher densities. The self-diffusion coefficient calculated with non-equilibrium molecular dynamic simulations at different temperatures and densities is in good agreement with other calculations fronl the literature. We use non-equilibrium molecular dynamics simulations to calculate the self-diffusion coefficient, D, of a Lennard Jones fluid over a wide density and temperature range. The change in self-diffusion coefficient with temperature decreases by increasing density. For density ρ* = ρσ3 = 0.84 we observe a peak at the value of the self-diffusion coefficient and the critical temperature T* = kT/ε = 1.25. The value of the self-diffusion coefficient strongly depends on system size. The data of the self-diffusion coefficient are fitted to a simple analytic relation based on hydrodynamic arguments. This correction scales as N-α, where α is an adjustable parameter and N is the number of particles. It is observed that the values of a 〈 1 provide quite a good correction to the simulation data. The system size dependence is very strong for lower densities, but it is not as strong for higher densities. The self-diffusion coefficient calculated with non-equilibrium molecular dynamic simulations at different temperatures and densities is in good agreement with other calculations fronl the literature.
作者 Ahmed Asad 吴江涛
机构地区 State Key Laboratory of Multiphase Flow in Power Engineering
出处 《Chinese Physics B》 SCIE EI CAS CSCD 2011年第10期362-367,共6页 中国物理B(英文版)
基金 supported by the National Natural Science Foundation of China (Grant No. 51076128) the National High Technology Research and Development Program of China (Grant No. 2009AA05Z107)
关键词 self-diffusion coefficient non-equilibrium molecular dynamic simulation Lennard Jonesfluid critical dynamics self-diffusion coefficient, non-equilibrium molecular dynamic simulation, Lennard Jonesfluid, critical dynamics
分类号 O35 [理学—流体力学]
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  • 3Mermin N D.Lattice gas with short-range pair interactionsand a singular coexistence-curve diameter[J].Physical Review Letters,1971,26(16):957-959.
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Chinese Physics B
2011年 第10期

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