Role of three-body interactions in formation of bulk viscosity in liquid argon

Lishchuk, Sergey V.

doi:10.1063/1.4704930

Cited by 10 publications

(5 citation statements)

References 49 publications

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“…(B) Many-body interactions do not noticeably affect the bulk viscosity in dilute states, contrary to the previously investigated case of dense fluids [72].…”

Section: Discussioncontrasting

confidence: 69%

“…Such a coarsegraining procedure, based on the Henderson theorem [67], is not necessarily applicable for nonequilibrium and inhomogeneous systems. Many-body interactions may affect the transport and interfacial properties of the fluids, as reported for a self-diffusion coefficient [68], shear viscosity [68][69][70][71], bulk viscosity [69,70,72], thermal conductivity [69,70], and gas-liquid surface tension [73,74]. In particular, many-body interatomic interactions were found to play a significant role in the formation of bulk viscosity in dense argon fluid [72].…”

Section: B Many-body Interactionmentioning

confidence: 80%

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Bulk viscosity of gaseous argon from molecular dynamics simulations

Alboul

Lishchuk

2022

Phys. Rev. E

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The bulk viscosity of dilute argon gas is calculated using molecular dynamics simulations in the temperature range 150-500 K and is found to be proportional to density squared in the investigated range of densities 0.001-1 kg m −3 . A comparison of the results obtained using Lennard-Jones and Tang-Toennies models of pair interaction potential reveals that the value of the bulk viscosity coefficient is sensitive to the choice of the pair interaction model. The inclusion of the Axilrod-Teller-Muto three-body interaction in the model does not noticeably affect the values of the bulk viscosity in dilute states, contrary to the previously investigated case of dense fluids.

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“…(B) Many-body interactions do not noticeably affect the bulk viscosity in dilute states, contrary to the previously investigated case of dense fluids [72].…”

Section: Discussioncontrasting

confidence: 69%

Section: B Many-body Interactionmentioning

confidence: 80%

Bulk viscosity of gaseous argon from molecular dynamics simulations

Alboul

Lishchuk

2022

Phys. Rev. E

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“…133 The Lennard-Jones interaction potential was used, which has demonstrated to resolve such small-scale dynamics adequately and hence successfully describes macroscopic transport in liquid noble gases. [134][135][136][137][138] In the present work, the bulk viscosity's autocorrelation function BA was sampled in the microcanonical (NVE) ensemble, utilizing the fully open source program ms2. 139 The necessary average energies ⟨E⟩ were determined by preceding canonical (NVT) ensemble simulations for the given pair of temperature and density.…”

Section: Molecular Dynamics Simulationmentioning

confidence: 99%

Bulk viscosity of liquid noble gases

Chatwell

Vrabec

2020

The Journal of Chemical Physics

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An equation of state for the bulk viscosity of liquid noble gases is proposed. On the basis of dedicated equilibrium molecular dynamics simulations, a multi-mode relaxation ansatz is used to obtain precise bulk viscosity data over a wide range of liquid states. From this dataset, the equation of state emerges as a two-parametric power function with both parameters showing a conspicuous saturation behavior over temperature. After passing a temperature threshold, the bulk viscosity is found to vary significantly over density, a behavior that resembles the frequency response of a one pole low-pass filter. The proposed equation of state is in good agreement with available experimental sound attenuation data.

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“…Here, tentative prediction on the shear viscosity of coal ash is carried out by the MD method, and the results are explained from the microscopic view. Shear viscosity was calculated adopting the Green–Kubo formula , where η is the viscosity, V is the volume, k B is the Boltzmann constant, P αβ denotes the off-diagonal stress tensor, and angular brackets represent the ensemble average.…”

Section: Results and Discussionmentioning

confidence: 99%

Ash Fusion Properties from Molecular Dynamics Simulation: Role of the Ratio of Silicon and Aluminum

Dai

Bai

et al. 2016

Energy Fuels

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Molecular dynamics simulations are adopted to investigate the effect of the ratio of silicon and aluminum (S/A) contents on ash fusion properties and to predict the theoretical melting points and viscosities. The melting points are identified by the variation of the volume and mean square displacement, while viscosities are calculated by the Green–Kubo formula. The melting point is determined to be higher for coal ash systems with higher S/A ratios. The analyses of the radial distribution function and oxygen contents are performed to illustrate the structural evolution during the melting process. The interactions of different types are analyzed to explain the trend of melting points for various S/A ratios. The main structural features during slag melting are found to be the conversion of the oxygen atoms from the tricluster type to the bridging type. The viscosities of the slag systems near melting points are determined to be correlated to the S/A ratio as well. The computational results from this work may provide new insight into the mechanism of slag tapping.

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Role of three-body interactions in formation of bulk viscosity in liquid argon

Cited by 10 publications

References 49 publications

Bulk viscosity of gaseous argon from molecular dynamics simulations

Bulk viscosity of gaseous argon from molecular dynamics simulations

Bulk viscosity of liquid noble gases

Ash Fusion Properties from Molecular Dynamics Simulation: Role of the Ratio of Silicon and Aluminum

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