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引用次数: 0
摘要
本文的目的是改进现有的从非理想瑞利气体推导瑞利-玻尔兹曼方程的证明(Bodineau 等人,载于 Invent Math 203:493-553, 2016),以获得更快的收敛速度。该方程是波尔兹曼方程的线性版本,描述了一小部分被标记粒子从热力学平衡状态受到扰动后的行为。这个线性方程是根据希尔伯特第六问题提出的微观牛顿定律推导出来的,比二次波尔兹曼方程更好理解,甚至可以在气体动力学描述的长时间尺度上得出结果。本文改进了之前证明的物理上较差的收敛速率,使其达到了更令人满意的速率,其收敛速率超过了指数级的收敛速率。
On the Derivation of the Linear Boltzmann Equation from the Nonideal Rayleigh Gas
This paper’s objective is to improve the existing proof of the derivation of the Rayleigh–Boltzmann equation from the nonideal Rayleigh gas (Bodineau et al. in Invent Math 203:493–553, 2016), yielding a far faster convergence rate. This equation is a linear version of the Boltzmann equation, describing the behavior of a small fraction of tagged particles having been perturbed from thermodynamic equilibrium. This linear equation, derived from the microscopic Newton laws as suggested by the Hilbert’s sixth problem, is much better understood than the quadratic Boltzmann equation, and even enable results on long time scales for the kinetic description of gas dynamics. The present paper improves the physically poor convergence rate that had been previously proved, into a much more satisfactory rate which is more than exponentially better.
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The Journal of Statistical Physics publishes original and invited review papers in all areas of statistical physics as well as in related fields concerned with collective phenomena in physical systems.
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