Implementation of probe rheology simulation technique in atomistically detailed molecular dynamics simulations

The probe rheology simulation technique is a technique for measuring the viscosity of a fluid by measuring the motion of an inserted probe particle. This approach has the benefit of greater potential accuracy at a lower computational cost than other conventional simulation techniques used for the ca...

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Bibliographic Details
Published in:Journal of computational chemistry 2023-06, Vol.44 (16), p.1484-1492
Main Authors: Nourian, Pouria, Peters, Andrew J.
Format: Article
Language:English
Subjects:
atomistic
Brownian motion
Diamonds
Dynamic mechanical properties
Face centered cubic lattice
Mechanical properties
Molecular dynamics
Newtonian liquids
Periodic variations
Perturbation methods
probe rheology
Rheological properties
Rheology
Simulation
Viscosity
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Summary:The probe rheology simulation technique is a technique for measuring the viscosity of a fluid by measuring the motion of an inserted probe particle. This approach has the benefit of greater potential accuracy at a lower computational cost than other conventional simulation techniques used for the calculation of mechanical properties, such as the Green–Kubo approach and nonequilibrium molecular dynamics simulations, and the potential to allow for sampling local variations of properties. This approach is implemented and demonstrated for atomistically detailed models. The viscosity of four different simple Newtonian liquids is calculated from both the Brownian motion (passive mode) and the forced motion (active mode) of an embedded probe particle. The probe particle is loosely modeled as a nano‐sized diamond particle: a rough sphere cut out of an FCC lattice made of carbon atoms. The viscosities obtained from the motion of the probe particle are compared with those obtained from the periodic perturbation method, and good agreement between the two sets of values is observed once the probe‐fluid interaction strength (i.e., εij in the pair‐wise Lennard–Jones interaction) is two times higher than their original values, and the artificial hydrodynamic interactions between the probe particle and its periodic images are accounted for. The success of the proposed model opens new opportunities for applying such a technique in the rheological characterization of local mechanical properties in atomistically detailed molecular dynamics simulations, which can be directly compared with or help guide experiments of similar nature. We implement the probe rheology simulation technique in atomistically detailed molecular dynamics simulations to measure the viscosity of liquids, thus opening up new opportunities for applying such a technique in the rheological characterization of local mechanical properties in simulations. The technique is validated and optimal parameters are detailed.
ISSN:0192-8651
1096-987X
DOI:10.1002/jcc.27099