Condensed Matter Physics, 2019, vol. 22, No. 1, 13601
DOI:10.5488/CMP.22.13601
arXiv:1903.11474
Title:
Hydrodynamic correlations in isotropic fluids and liquid crystals simulated by multi-particle collision dynamics
Author(s):
 
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H. Híjar
(Engineering School, La Salle University Mexico, Benjamin Franklin 45, 06140, Mexico City, Mexico)
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Multi-particle collision dynamics is an appealing numerical technique aiming at simulating fluids at the mesoscopic scale. It considers molecular details in a coarse-grained
fashion and reproduces hydrodynamic phenomena. Here, the implementation of multi-particle collision dynamics for isotropic fluids is analysed under the so-called Andersen-thermostatted
scheme, a particular algorithm for systems in the canonical ensemble. This method gives rise to hydrodynamic fluctuations that spontaneously relax towards equilibrium. This relaxation
process can be described by a linearized theory and used to calculate transport coefficients of the system. The extension of the algorithm for nematic liquid crystals is also considered.
It is shown that thermal fluctuations in the average molecular orientation can be described by an extended linearized scheme. Flow fluctuations induce orientation fluctuations. However,
orientational changes produce observable effects on velocity correlation functions only when simulation parameters exceed their values from those used in previous applications of the method.
Otherwise, the flow can be considered to be independent of the orientation field.
Key words:
multi-scale simulation techniques, particle-based simulations of fluids, thermal fluctuations, nematic liquid crystals, structure of liquids and liquid crystals
PACS:
61.20.Ja, 05.20.Jj, 05.40.-a, 83.80.Xz
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