Two-time energy spectrum of weak magnetohydrodynamic turbulence

J. C. Perez, Augustus A. Azelis, S. Bourouaine
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引用次数: 2

Abstract

In this work a weak-turbulence closure is used to determine the structure of the two-time power spectrum of weak magnetohydrodynamic (MHD) turbulence from the nonlinear equations describing the dynamics. The two-time energy spectrum is a fundamental quantity in turbulence theory from which most statistical properties of a homogeneous turbulent system can be derived. A closely related quantity, obtained via a spatial Fourier transform, is the two-point two-time correlation function describing the space-time correlations arising from the underlying dynamics of the turbulent fluctuations. Both quantities are central in fundamental turbulence theories as well as in the analysis of turbulence experiments and simulations. However, a first-principles derivation of these quantities has remained elusive due to the statistical closure problem, in which dynamical equations for correlations at order $n$ depend on correlations of order $n+1$. The recent launch of the Parker Solar Probe (PSP), which will explore the near-Sun region where the solar wind is born, has renewed the interest in the scientific community to understand the structure, and possible universal properties of space-time correlations. The weak MHD turbulence regime that we consider in this work allows for a natural asymptotic closure of the two-time spectrum, which may be applicable to other weak turbulence regimes found in fluids and plasmas. An integro-differential equation for the scale-dependent temporal correlation function is derived for incompressible Alfvenic fluctuations whose nonlinear dynamics is described by the reduced MHD equations.
弱磁流体动力学湍流的二次能谱
本文采用弱湍流闭包从描述弱磁流体动力学的非线性方程中确定弱磁流体动力学(MHD)湍流的二次功率谱结构。双时间能谱是湍流理论中的一个基本量,从它可以推导出均匀湍流系统的大多数统计性质。通过空间傅里叶变换获得的一个密切相关的量是两点两时间相关函数,它描述了由湍流波动的潜在动力学引起的时空相关性。这两个量在基本湍流理论以及湍流实验和模拟分析中都是中心。然而,由于统计闭包问题,这些量的第一性原理推导仍然难以捉摸,其中n阶相关性的动力学方程依赖于n+1阶相关性。最近发射的帕克太阳探测器(PSP)将探索太阳风产生的近太阳区域,它重新燃起了科学界对理解时空相关性的结构和可能的普遍特性的兴趣。我们在这项工作中考虑的弱MHD湍流状态允许两时间谱的自然渐近闭合,这可能适用于在流体和等离子体中发现的其他弱湍流状态。导出了不可压缩Alfvenic波动的尺度相关时间相关函数的积分-微分方程,该波动的非线性动力学由简化的MHD方程描述。
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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