Dissipative systems have a maximum energy rate density of 105 W/kg

IF 1.6 4区 物理与天体物理 Q3 PHYSICS, CONDENSED MATTER The European Physical Journal B Pub Date : 2024-11-04 DOI:10.1140/epjb/s10051-024-00785-2
Martin van Duin
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Abstract

Mass and energy rate (ER) data have been collected for a wide variety of dissipative systems from the biological, cultural, and cosmological realms. They range from 6 × 10–25 kg and 3 × 10–25 W for a synthetic, molecular engine to 1.5 × 1053 kg and 1048 W for the observable universe and, thus, span 78 mass and 73 ER orders of magnitude, respectively. The combination of (i) convergence of smaller systems (parts) to a larger system and (ii) scaling of ER as a function of mass with a power law constant β > 0 for groups of systems, explains why the ER and mass data points fall in a diagonal band in the double logarithmic ER vs. mass master plot. There appears to be an ER vs. mass limit, corresponding to an energy rate density (ERD = ER/mass) of around 105 W/kg, separating stable, dissipative systems from unstable, “explosive” systems (atomic weapons, supernova, etc.) in all realms. This limit is probably the result of a balance between the energy flow through a system, resulting in increased temperature and pressure, and the strength of the system’s structure and boundary. ERD has been proposed as a metric for the development of the complexity of dissipative systems over deep time Chaisson (Cosmic evolution; The rise of complexity in nature. Harvard University Press, Cambridge, 2002), Chaisson (Sci World J 384912, 2014). Thus, the observed ERD threshold of 105 W/kg may correspond to a maximum of complexity. Several ways to further increase complexity while circumventing this ERD limit are proposed.

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耗散系统的最大能量密度为 105 W/kg
我们已经收集了来自生物、文化和宇宙学领域的各种耗散系统的质量和能量速率(ER)数据。它们的范围从合成分子引擎的 6 × 10-25 千克和 3 × 10-25 瓦到可观测宇宙的 1.5 × 1053 千克和 1048 瓦,因此分别跨越了 78 个质量数量级和 73 个能量数量级。(i)较小的系统(部分)向较大的系统靠拢,(ii)ER 与质量的函数缩放,对于系统组来说,幂律常数 β > 0,这两个因素的结合解释了为什么 ER 和质量数据点落在 ER 与质量双对数主图的对角线带上。ER与质量的关系似乎存在一个极限,对应于大约105瓦/千克的能量率密度(ERD = ER/质量),在所有领域中将稳定的耗散系统与不稳定的 "爆炸 "系统(原子武器、超新星等)区分开来。这一极限可能是能量流经系统(导致温度和压力升高)与系统结构和边界强度之间平衡的结果。有人提出,ERD 是耗散系统的复杂性随深度时间发展的度量标准,柴森(《宇宙演化;自然界复杂性的崛起》,哈佛大学出版社,剑桥。哈佛大学出版社,剑桥,2002 年),Chaisson(科学世界 J 384912,2014 年)。因此,观测到的ERD阈值105 W/kg可能对应于复杂性的最大值。本文提出了几种在规避ERD限制的同时进一步提高复杂性的方法。
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
The European Physical Journal B
The European Physical Journal B 物理-物理:凝聚态物理
CiteScore
2.80
自引率
6.20%
发文量
184
审稿时长
5.1 months
期刊介绍: Solid State and Materials; Mesoscopic and Nanoscale Systems; Computational Methods; Statistical and Nonlinear Physics
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