Scaling Up: Molecular to Meteorological via Symmetry Breaking and Statistical Multifractality

Agricultural Meteorology Pub Date : 2022-02-24 DOI:10.3390/meteorology1010003

A. Tuck

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引用次数: 4

Abstract

The path from molecular to meteorological scales is traced and reviewed, beginning with the persistence of molecular velocity after collision induces symmetry breaking, from continuous translational to scale invariant, associated with the emergence of hydrodynamic behaviour in a Maxwellian (randomised) population undergoing an anisotropic flux. An empirically based formulation of entropy and Gibbs free energy is proposed and tested with observations of temperature, wind speed and ozone. These theoretical behaviours are then succeeded upscale by key results of statistical multifractal analysis of airborne observations on horizontal scales from 40 m to an Earth radius, and on vertical scales from the surface to 13 km. Radiative, photochemical and dynamical processes are then examined, with the intermittency of temperature implying significant consequences. Implications for vertical scaling of the horizontal wind are examined via the thermal wind and barometric equations. Experimental and observational tests are suggested for free running general circulation models, with the possibility of addressing the cold bias they still exhibit. The causal sequence underlying atmospheric turbulence is proposed.

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放大:通过对称破缺和统计多重分形从分子到气象

从分子尺度到气象尺度的路径被追踪和回顾，从碰撞诱导对称破断后分子速度的持久性开始，从连续平移到尺度不变，与经历各向异性通量的麦克斯韦(随机)种群中出现的流体动力学行为相关。提出了一种基于经验的熵和吉布斯自由能公式，并用温度、风速和臭氧的观测结果进行了验证。在40米至地球半径的水平尺度和13公里的垂直尺度上，航空观测数据的统计多重分形分析的关键结果进一步证实了这些理论行为。然后检查辐射、光化学和动力学过程，温度的间歇性意味着显著的后果。通过热风和气压方程考察了水平风的垂直尺度的含义。建议对自由运行的一般环流模式进行实验和观测检验，有可能解决它们仍然表现出的冷偏。提出了大气湍流的因果序列。

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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Agricultural Meteorology

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