Moderately dense granular gas of inelastic rough spheres

Journal of Physics A: Mathematical and Theoretical Pub Date : 2024-05-13 DOI:10.1088/1751-8121/ad4aa6

Gilberto M Kremer

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Abstract

A kinetic theory for moderately dense gases of inelastic and rough spherical molecules is developed from the Enskog equation where a macroscopic state is characterised by 29 scalar fields which correspond to the moments of the distribution function: mass density, hydrodynamic velocity, pressure tensor, absolute temperature, translational and rotational heat fluxes, hydrodynamic angular velocity and angular velocity flux. The balance equations for the 29 scalar fields are obtained from a transfer equation derived from the Enskog equation where the kinetic and potential parts of the new moments of the distribution function and production terms are calculated from Grad's distribution function for the basic fields. The transition from the 29 field theory to an eight field theory -- with mass density hydrodynamic velocity, absolute temperature and hydrodynamic angular velocity -- leads to the determination of the transport coefficients of the Navier-Stokes and Fourier laws. The transport coefficients are functions of the normal and tangential restitution coefficients and of the local equilibrium radial distribution function. The transport coefficients in the limiting case of elastic rough spheres is also determined.

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由非弹性粗糙球体组成的中等密度颗粒气体

根据恩斯科格方程建立了非弹性和粗糙球形分子的中等密度气体动力学理论，其中宏观状态由 29 个标量场表征，这些标量场与分布函数的矩相对应：质量密度、流体力学速度、压力张量、绝对温度、平移和旋转热通量、流体力学角速度和角速度通量。29 个标量场的平衡方程是从恩斯科格方程导出的转移方程中得到的，其中分布函数新矩阵的动能和势能部分以及产生项是从基本场的格拉德分布函数中计算出来的。从 29 场理论到八场理论--质量密度流体力学速度、绝对温度和流体力学角速度--的过渡导致了纳维-斯托克斯定律和傅里叶定律的传输系数的确定。输运系数是法向和切向复原系数以及局部平衡径向分布函数的函数。此外，还确定了弹性粗糙球体极限情况下的传输系数。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Physics A: Mathematical and Theoretical

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