Applying the Action Principle of Classical Mechanics to the Thermodynamics of the Troposphere

IF 12.2 1区 工程技术 Q1 MECHANICS
I. Kennedy, M. Hodzic
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Abstract

Advances in applied mechanics have facilitated a better understanding of the recycling of heat and work in the troposphere. This goal is important to meet practical needs for better management of climate science. Achieving this objective may require the application of quantum principles in action mechanics, recently employed to analyze the reversible thermodynamics of Carnot’s heat engine cycle. The testable proposals suggested here seek to solve several problems including (i) the phenomena of decreasing temperature and molecular entropy but increasing Gibbs energy with altitude in the troposphere; (ii) a reversible system storing thermal energy to drive vortical wind flow in anticyclones while frictionally warming the Earth’s surface by heat release from turbulence; (iii) vortical generation of electrical power from translational momentum in airflow in wind farms; and (iv) vortical energy in the destructive power of tropical cyclones. The scalar property of molecular action (@t ≡ ∫mvds, J-sec) is used to show how equilibrium temperatures are achieved from statistical equality of mechanical torques (mv2 or mr2ω2); these are exerted by Gibbs field quanta for each kind of gas phase molecule as rates of translational action (d@t/dt ≡ ∫mr2ωdϕ/dt ≡ mv2). These torques result from the impulsive density of resonant quantum or Gibbs fields with molecules, configuring the trajectories of gas molecules while balancing molecular pressure against the density of field energy (J/m3). Gibbs energy fields contain no resonant quanta at zero Kelvin, with this chemical potential diminishing in magnitude as the translational action of vapor molecules and quantum field energy content increases with temperature. These cases distinguish symmetrically between causal fields of impulsive quanta (Σhν) that energize the action of matter and the resultant kinetic torques of molecular mechanics (mv2). The quanta of these different fields display mean wavelengths from 10−4 m to 1012 m, with radial mechanical advantages many orders of magnitude greater than the corresponding translational actions, though with mean quantum frequencies (v) similar to those of radial Brownian movement for independent particles (ω). Widespread neglect of the Gibbs field energy component of natural systems may be preventing advances in tropospheric mechanics. A better understanding of these vortical Gibbs energy fields as thermodynamically reversible reservoirs for heat can help optimize work processes on Earth, delaying the achievement of maximum entropy production from short-wave solar radiation being converted to outgoing long-wave radiation to space. This understanding may improve strategies for management of global changes in climate.
经典力学作用原理在对流层热力学中的应用
应用力学的进步促进了对对流层中热量和功的再循环的更好理解。这一目标对于满足更好地管理气候科学的实际需要很重要。实现这一目标可能需要在作用力学中应用量子原理,最近用于分析卡诺热机循环的可逆热力学。本文提出的可验证性建议试图解决以下几个问题:(1)对流层温度和分子熵随高度降低而吉布斯能随高度增加的现象;(ii)一个可逆的系统,储存热能,驱动反气旋中的垂直气流,同时通过湍流释放的热量摩擦地使地球表面变暖;(iii)风力发电场中气流的平动动量产生的涡旋发电;(四)热带气旋破坏力中的涡旋能。分子作用的标量性质(@t≡∫mvds, J-sec)用于显示如何从机械扭矩(mv2或mr2ω2)的统计相等中获得平衡温度;这些是由吉布斯场量子对每种气相分子施加的平动作用速率(d@t/dt≡∫mr2ω ϕ/dt≡mv2)。这些扭矩来自分子共振量子场或吉布斯场的脉冲密度,在平衡分子压力和场能密度(J/m3)的同时,配置了气体分子的轨迹。在零开尔文时,吉布斯能量场不包含共振量子,随着蒸汽分子的平移作用和量子场能量含量随温度的增加,这种化学势的大小逐渐减小。这些情况对称地区分了脉冲量子的因果场(Σhν),这些量子为物质的作用提供了能量,而分子力学的结果是动力学扭矩(mv2)。这些不同场的量子显示出从10−4 m到1012 m的平均波长,具有比相应的平移作用大许多数量级的径向力学优势,尽管平均量子频率(v)与独立粒子的径向布朗运动(ω)相似。对自然系统吉布斯场能量分量的普遍忽视可能阻碍了对流层力学的进展。更好地理解这些涡旋吉布斯能量场作为热力学可逆的热储,可以帮助优化地球上的工作过程,延迟实现从短波太阳辐射转换为向外的长波辐射到太空的最大熵产。这种认识可以改善管理全球气候变化的战略。
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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来源期刊
CiteScore
28.20
自引率
0.70%
发文量
13
审稿时长
>12 weeks
期刊介绍: Applied Mechanics Reviews (AMR) is an international review journal that serves as a premier venue for dissemination of material across all subdisciplines of applied mechanics and engineering science, including fluid and solid mechanics, heat transfer, dynamics and vibration, and applications.AMR provides an archival repository for state-of-the-art and retrospective survey articles and reviews of research areas and curricular developments. The journal invites commentary on research and education policy in different countries. The journal also invites original tutorial and educational material in applied mechanics targeting non-specialist audiences, including undergraduate and K-12 students.
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