书评:自然和工业过程中的旋转热流

IF 1.3 Q3 THERMODYNAMICS
J. Reizes
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In fact, one can almost imagine the author exclaim as he writes, as is attested by his comment “The incredible richness of convective modes”—and this is only about RayleighBenard convection with rotation. The range of scales presented is truly prodigious— from giant gas planets and atmospheric phenomena to crystal growth. The amount of material presented is therefore quite large, so to keep the manuscript to a reasonable length, it seems to me that the author has had to condense the explanations to the bare minimum. As a consequence it makes for difficult reading. Should the reader put the book down for a few days before resuming reading, the lack of a nomenclature and the use of the same symbol for a number of variables as well as the use of many acronyms make it even more difficult to read. The first chapter, entitled “Equations, General Concepts and Nondimensional Numbers,” lays the foundation for the remainder of the book. 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The author deplores the fact that because he had to restrict the length of the book, a “cross-link between macroand micro-scales” has not been presented so that “the Navier-Stokes and energy equations are presented directly.” This is not an elementary textbook and would, I expect, be intended for research students and researchers, and I see no need for such a development in the pages of this book, particularly as that had appeared in the “Thermal Convection” volume. Similarly, had the phenomena presented not been idealized by the use of the Boussinesq approximation, the length of the book would have been intolerable and it would not have been published. 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The range of scales presented is truly prodigious— from giant gas planets and atmospheric phenomena to crystal growth. The amount of material presented is therefore quite large, so to keep the manuscript to a reasonable length, it seems to me that the author has had to condense the explanations to the bare minimum. As a consequence it makes for difficult reading. Should the reader put the book down for a few days before resuming reading, the lack of a nomenclature and the use of the same symbol for a number of variables as well as the use of many acronyms make it even more difficult to read. The first chapter, entitled “Equations, General Concepts and Nondimensional Numbers,” lays the foundation for the remainder of the book. 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引用次数: 0

摘要

与Lappa的早期著作《热对流:模式、演变和稳定性》(Wiley, 2010)一样,这本书不是关于热传递的。这本书的重点是关于流动的流体力学在旋转系统中,热梯度是存在的。再次,与前一卷类似,重点是这种流动的物理和数学处理;特别是这些流动的稳定性。因此,没有讨论数值或实验程序。计算模拟和复杂实验的结果被用来说明和发展正在讨论的思想。这本书几乎是一个介绍在旋转系统的热流,并不是为一个新手设计的主题。更确切地说,它是一次穿越物理学之旅,探索在这种情况下发生的无数奇迹。事实上,我们几乎可以想象作者在写作时的感叹,正如他的评论“对流模式的不可思议的丰富”所证明的那样——这只是关于瑞利-贝纳德旋转对流。所呈现的尺度范围确实是惊人的——从巨大的气体行星和大气现象到晶体生长。因此,所呈现的材料数量相当大,因此,为了使手稿保持合理的长度,在我看来,作者不得不将解释压缩到最低限度。因此,它使阅读变得困难。如果读者把书放下几天再继续阅读,缺乏术语,对许多变量使用相同的符号,以及使用许多首字母缩略词,使它更难以阅读。第一章,题为“方程,一般概念和无量纲数,”奠定了本书的其余部分的基础。其余章节的标题是:瑞利-贝纳德对流与旋转;球壳、罗斯比波与离心驱动热对流斜压问题;准地转问题;行星模式;旋转流体表面张力驱动流动研究熔体和旋转机械的晶体生长旋转磁场;角振动和摇摆运动。本书的主要重点是流的稳定性,最后三章更多地针对应用程序。所涉及的内容,虽然有时简要介绍,但一般来说非常广泛,37页的参考资料清楚地证实了这一点。书中的内容太多了,不可能具体讨论任何一个主题,所以我将限制自己对基本原理的一些评论。作者感到遗憾的是,由于他不得不限制书的长度,没有提出“宏观和微观尺度之间的交叉联系”,因此“直接提出了纳维-斯托克斯方程和能量方程”。这不是一本基础教科书,我希望它是为研究生和研究人员准备的,我认为在这本书的页面中不需要这样的发展,特别是在“热对流”卷中出现的发展。同样,如果没有使用Boussinesq近似将所呈现的现象理想化,这本书的长度将是无法忍受的,也不会出版。当然,这使作者能够摆脱“现实世界”效应所产生的问题,这些问题使数值生成的结果与实验数据的比较相当困难。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
BOOK REVIEW: ROTATING THERMAL FLOWS IN NATURAL AND INDUSTRIAL PROCESSES
As with Lappa’s earlier book, “Thermal Convection: Patterns, Evolution and Stability” (Wiley, 2010), this book is not about heat transfer. The focus of the book is about the fluid mechanics of flows in rotating systems in which thermal gradients are present. Again, similar to the previous volume, the emphasis is on the physics and the mathematical treatments of such flows; in particular the stability of these flows. There is therefore no discussion of either numerical or experimental procedures. The results of computational simulations and complex experiments are used to illustrate and develop the ideas being discussed. This book is hardly an introduction to thermal flows in rotating systems and is not designed for a novice in the subject. Rather, it is a voyage through the physics of a myriad of wonders which occur in such situations. In fact, one can almost imagine the author exclaim as he writes, as is attested by his comment “The incredible richness of convective modes”—and this is only about RayleighBenard convection with rotation. The range of scales presented is truly prodigious— from giant gas planets and atmospheric phenomena to crystal growth. The amount of material presented is therefore quite large, so to keep the manuscript to a reasonable length, it seems to me that the author has had to condense the explanations to the bare minimum. As a consequence it makes for difficult reading. Should the reader put the book down for a few days before resuming reading, the lack of a nomenclature and the use of the same symbol for a number of variables as well as the use of many acronyms make it even more difficult to read. The first chapter, entitled “Equations, General Concepts and Nondimensional Numbers,” lays the foundation for the remainder of the book. The remaining chapters are entitled: Rayleigh-Benard Convection with Rotation; Spherical Shells, Rossby Waves and Centrifugally Driven Thermal Convection; The Baroclinic Problem; The Quasi-Geostrophic Problem; Planetary Patterns; Surface Tension Driven Flows in Rotating Fluids; Crystal Growth from the Melt and Rotating Machinery; Rotating Magnetic Fields; and Angular Vibrations and Rocking Motion. The main emphasis of the book is on the stability of the flows with the last three chapters directed more to applications. The coverage, albeit briefly presented at times, is generally very extensive as the 37 pages of references clearly confirm. There is so much in the book that it is impossible to discuss any one topic in particular, so I will confine myself to a couple of remarks about fundamentals. The author deplores the fact that because he had to restrict the length of the book, a “cross-link between macroand micro-scales” has not been presented so that “the Navier-Stokes and energy equations are presented directly.” This is not an elementary textbook and would, I expect, be intended for research students and researchers, and I see no need for such a development in the pages of this book, particularly as that had appeared in the “Thermal Convection” volume. Similarly, had the phenomena presented not been idealized by the use of the Boussinesq approximation, the length of the book would have been intolerable and it would not have been published. This, of course, allows the author to free himself of the problems which occur from “real world” effects which make comparisons of numerically generated results with experimental data quite difficult.
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来源期刊
CiteScore
2.70
自引率
6.70%
发文量
36
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