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RECORD NUMBER: 3 OF 447

OLS Field Name OLS Field Data
Main Title A first course in turbulence /
Author Tennekes, H. ; Lumley, John Leask
Publisher The MIT Press,
Year Published 1972
OCLC Number 00281992
ISBN 0262200198; 9780262200196; 0262536307; 9780262536301
Subjects Turbulence. ; Dimensional analysis. ; Turbulente Strèomung ; Turbulentie. ; Hydrodynamica. ; Analyse dimensionnelle.
Additional Subjects Turbulence ; Dimensional analysis
Internet Access
Description Access URL
http://ieeexplore.ieee.org/servlet/opac?bknumber=6276829
Holdings
Library Call Number Additional Info Location Last
Modified
Checkout
Status
EHAM  QA913.T44 Region 1 Library/Boston,MA 01/01/1988
EKBM  QA913.T44 1972 Research Triangle Park Library/RTP, NC 08/31/2011
Collation xii, 300 pages : illustrations ; 24 cm
Notes
Includes bibliographical references (pages 288-293) and index.
Contents Notes
The subject of turbulence, the most forbidding in fluid dynamics, has usually proved treacherous to the beginner, caught in the whirls and eddies of its nonlinearities and statistical imponderables. This is the first book specifically designed to offer the student a smooth transitionary course between elementary fluid dynamics (which gives only last-minute attention to turbulence) and the professional literature on turbulent flow, where an advanced viewpoint is assumed. Moreover, the text has been developed for students, engineers, and scientists with different technical backgrounds and interests. Almost all flows, natural and man-made, are turbulent. Thus the subject is the concern of geophysical and environmental scientists (in dealing with atmospheric jet streams, ocean currents, and the flow of rivers, for example), of astrophysicists (in studying the photospheres of the sun and stars or mapping gaseous nebulae), and of engineers (in calculating pipe flows, jets, or wakes). Many such examples are discussed in the book. The approach taken avoids the difficulties of advanced mathematical development on the one side and the morass of experimental detail and empirical data on the other. As a result of following its midstream course, the text gives the student a physical understanding of the subject and deepens his intuitive insight into those problems that cannot now be rigorously solved. In particular, dimensional analysis is used extensively in dealing with those problems whose exact solution is mathematically elusive. Dimensional reasoning, scale arguments, and similarity rules are introduced at the beginning and are applied throughout. A discussion of Reynolds stress and the kinetic theory of gases provides the contrast needed to put mixing-length theory into proper perspective: the authors present a thorough comparison between the mixing-length models and dimensional analysis of shear flows. This is followed by an extensive treatment of vorticity dynamics, including vortex stretching and vorticity budgets. Two chapters are devoted to boundary-free shear flows and well-bounded turbulent shear flows. The examples presented include wakes, jets, shear layers, thermal plumes, atmospheric boundary layers, pipe and channel flow, and boundary layers in pressure gradients. The spatial structure of turbulent flow has been the subject of analysis in the book up to this point, at which a compact but thorough introduction to statistical methods is given. This prepares the reader to understand the stochastic and spectral structure of turbulence. The remainder of the book consists of applications of the statistical approach to the study of turbulent transport (including diffusion and mixing) and turbulent spectra. Introduction -- Turbulent transport of momentum and heat -- The dynamics of turbulence -- Boundary-free shear flows -- Wall-bounded shear flows -- The statistical description of turbulence -- Turbulent transport -- Spectral dynamics.