Drag force through gases and plasma

Annals of Mathematics and Physics Pub Date : 2022-01-25 DOI:10.17352/amp.000031
A. M.
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Abstract

The drag force in a gas (previously derived by Stokes and Rayleigh) is derived by means of the molecular kinetics (transport equation of the momentum). Two regimes of resistance to motion are identified, governed by the relation of the velocity to the thermal (molecular) velocity. They correspond to the molecular movement, for small velocities, or to the hydrodynamic motion for high velocities. In the former case sound waves are not excited, and energy is dissipated by viscosity (friction), while in the latter case the energy is dissipated by the excitation of the sound waves. Also, the treatment is applied to the plasma. It is shown that in usual plasmas it is unlikely that the body motion excites plasmons.
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阻力通过气体和等离子体
气体中的阻力(以前由斯托克斯和瑞利推导)是通过分子动力学(动量的传递方程)推导出来的。确定了两种运动阻力,由速度与热(分子)速度的关系决定。它们对应于小速度时的分子运动,或者对应于高速时的流体动力学运动。在前一种情况下,声波没有被激发,能量因粘度(摩擦)而耗散,而在后一种情况下,能量因声波的激发而耗散。同样,该处理也适用于等离子体。结果表明,在通常的等离子体中,身体运动不太可能激发等离子体。
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Annals of Mathematics and Physics
Annals of Mathematics and Physics
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