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Rotational viscosity of fluids composed of linear molecules: An equilibrium molecular dynamics study

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posted on 2024-07-26, 14:11 authored by R. J D Moore, J. S. Hansen, Billy ToddBilly Todd
In this paper, we investigate the rotational viscosity for a chlorine fluid and for a fluid composed of small linear molecules by using equilibrium molecular dynamics simulations. The rotational viscosity is calculated over a large range of state points. It is found that the rotational viscosity is almost independent of temperature in the range studied here but exhibits a power-law dependency on density. The rotational viscosity also shows a power-law relationship with the molecular length, and the ratio between the shear and rotational viscosities approaches 0.5 for the longest molecule studied here. By changing the number of atoms or united atomic units per molecule and by keeping the molecule length fixed, we show that fluids composed of molecules which have a rodlike shape have a lower rotational viscosity. We argue that this phenomenon is due to the reduction in intermolecular connectivity, which leads to larger fluctuations around the values possessed by the fluid on average. The conclusions here can be extended to fluids composed of uniaxial molecules of arbitrary length.

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ISSN

0021-9606

Journal title

Journal of Chemical Physics

Volume

128

Issue

22

Article number

article no. 224507

Pagination

1 p

Publisher

American Institute of Physics

Copyright statement

Copyright © 2008 American Institute of Physics. The published version is reproduced in accordance with the copyright policy of the publisher.

Language

eng

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