Stochastic Dissipative Euler's equations for a free body

arXiv - PHYS - Classical Physics Pub Date : 2024-04-25 DOI:arxiv-2404.16613

J. A. de la Torre, J. Sánchez-Rodríguez, Pep Español

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Abstract

Intrinsic thermal fluctuations within a real solid challenge the rigid body assumption that is central to Euler's equations for the motion of a free body. Recently, we have introduced a dissipative and stochastic version of Euler's equations in a thermodynamically consistent way (European Journal of Mechanics - A/Solids 103, 105184 (2024)). This framework describes the evolution of both orientation and shape of a free body, incorporating internal thermal fluctuations and their concomitant dissipative mechanisms. In the present work, we demonstrate that, in the absence of angular momentum, the theory predicts that principal axis unit vectors of a body undergo an anisotropic Brownian motion on the unit sphere, with the anisotropy arising from the body's varying moments of inertia. The resulting equilibrium time correlation function of the principal eigenvectors decays exponentially. This theoretical prediction is confirmed in molecular dynamics simulations of small bodies. The comparison of theory and equilibrium MD simulations allow us to measure the orientational diffusion tensor. We then use this information in the Stochastic Dissipative Euler's Equations, to describe a non-equilibrium situation of a body spinning around the unstable intermediate axis. The agreement between theory and simulations is excellent, offering a validation of the theoretical framework.

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自由体的随机耗散欧拉方程

最近，我们以热力学一致的方式引入了欧拉方程的耗散和随机版本（《欧洲力学杂志-固体》103，105184 (2024)）。这一框架描述了自由体的方向和形状的演变，其中包含内部热波动及其伴随的耗散机制。在本研究中，我们证明了在没有角动量的情况下，该理论预测物体的主轴单位矢量在单位球面上会发生各向异性的布朗运动，其各向异性源于物体不断变化的惯性矩。由此产生的主要特征向量的平衡时间相关函数呈指数衰减。这一理论预测在小体的分子动力学模拟中得到了证实。通过理论与平衡 MD 模拟的比较，我们可以测量取向扩散张量。然后，我们利用随机耗散欧拉方程中的这一信息，描述了围绕不稳定中间轴旋转的物体的非平衡状态。理论与模拟之间的一致性非常好，为理论框架提供了验证。

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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arXiv - PHYS - Classical Physics

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