Molecular kinetic modelling of non-equilibrium transport of confined van der Waals fluids

Shan, Baochao; Su, Wei; Gibelli, Livio; Zhang, Yonghao

doi:10.1017/jfm.2023.893

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Cited by 4 publications

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General synthetic iterative scheme for non-equilibrium dense gas flows

Shi,

Zhang,

2025

Journal of Computational Physics

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General synthetic iterative scheme for non-equilibrium dense gas flows

Shi,

Zhang,

2025

Journal of Computational Physics

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Impact of random nanoscale roughness on gas-scattering dynamics

Chen,

Gibelli,

Borg

2024

Phys. Rev. E

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The impact of nanoscale wall roughness on rarefied gas transport is widely acknowledged, yet the associated scattering dynamics largely remain elusive. In this paper, we develop a scattering kernel for surfaces having nanoscale roughness that distinctly characterizes the two major types of interactions between gas molecules and rough surfaces. Namely these are (a) the weak perturbations arising from the thermal motion of wall atoms, essentially gas-phonon collisions, which are captured by the well-established Cercignani-Lampis model, and (b) the hard collisions owing to the irregularities of the rough, static potential energy surface, which are generally described by the fully diffuse model. Drawing an analogy between wave-surface and gas-surface scattering, a pseudo Debye-Waller factor is incorporated into the modeling as a weighting coefficient to allow the transition between smooth and rough surface conditions. The proposed scattering kernel is validated through high-fidelity molecular dynamics simulations that are performed for systems with varying roughness, temperature, and gas-surface combinations. The results indicate that the model well captures the scattering dynamics of gas molecular beams impinging on surfaces at different velocities, specifically for the accommodation coefficients and reflection patterns. Additionally, in flow and heat transport cases, it accurately predicts macroscopic quantities such as velocity slip and temperature jumps across the range of tested conditions. Published by the American Physical Society 2024

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Mesoscopic lattice Boltzmann modeling of dense gas flows in curvilinear geometries

Busuioc

2024

Phys. Rev. Fluids

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Molecular kinetic modelling of non-equilibrium transport of confined van der Waals fluids

Cited by 4 publications

References 93 publications

General synthetic iterative scheme for non-equilibrium dense gas flows

General synthetic iterative scheme for non-equilibrium dense gas flows

Impact of random nanoscale roughness on gas-scattering dynamics

Mesoscopic lattice Boltzmann modeling of dense gas flows in curvilinear geometries

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