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Ten chapters in turbulenceedited by Peter A. Davidson, Yukio Kaneda, Katepalli R. Sreenivasan.

Contributor(s): Material type: TextTextPublication details: Cambridge : Cambridge University Press, (c)2013.Description: 1 online resource (xii, 437 pages)Content type:
  • text
Media type:
  • computer
Carrier type:
  • online resource
ISBN:
  • 9781139839761
Subject(s): Genre/Form: LOC classification:
  • QA913 .T463 2013
Online resources: Available additional physical forms:
Contents:
inthe Light of High Resolution Direct Numerical Simulation; 1.1 Introduction; 1.2 Background supporting the idea of universality; 1.3 Examination of the ideas underlying the 4/5 law; 1.4 Intermittency of dissipation rate and velocity gradients; 1.5 Local structure; 1.6 Inertial subrange; 1.7 Concluding remarks; References; 2 Structure and Dynamics of Vorticity in Turbulence; 2.1 Introduction; 2.2 Basic relations; 2.3 Temporal growth of vorticity; 2.4 Spatial structure of the turbulent vorticity field
Subject: Leading experts summarize our current understanding of the fundamental nature of turbulence, covering a wide range of topics.
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Item type Current library Collection Call number URL Status Date due Barcode
Online Book (LOGIN USING YOUR MY CIU LOGIN AND PASSWORD) Online Book (LOGIN USING YOUR MY CIU LOGIN AND PASSWORD) G. Allen Fleece Library ONLINE Non-fiction QA913 (Browse shelf(Opens below)) Link to resource Available ocn819623912

Includes bibliographical references.

Description based upon print version of record.

Preface; Contributors; 1 Small-Scale Statistics and Structure of Turbulence -- inthe Light of High Resolution Direct Numerical Simulation; 1.1 Introduction; 1.2 Background supporting the idea of universality; 1.3 Examination of the ideas underlying the 4/5 law; 1.4 Intermittency of dissipation rate and velocity gradients; 1.5 Local structure; 1.6 Inertial subrange; 1.7 Concluding remarks; References; 2 Structure and Dynamics of Vorticity in Turbulence; 2.1 Introduction; 2.2 Basic relations; 2.3 Temporal growth of vorticity; 2.4 Spatial structure of the turbulent vorticity field

2.5 Vorticity statistics in turbulenceReferences; 3 Passive Scalar Transport in Turbulence:A Computational Perspective; 3.1 Introduction; 3.2 Computational perspective; 3.3 Background theory; 3.4 Approach to low-order asymptotic state; 3.5 High-order statistics: fine-scale structure and intermittency; 3.6 Concluding remarks; References; 4 A Lagrangian View of Turbulent Dispersion and Mixing; 4.1 Introduction; 4.2 Single particle motion and absolute dispersion; 4.3 Two particle motion and relative dispersion; 4.4 n-particle statistics; 4.5 Conclusions; References

5 The Eddies and Scales of Wall Turbulence5.1 Introduction; 5.2 Background; 5.3 Scales of coherent structures in wall turbulence; 5.4 Relationship between statistical fine-scales and eddyscales; 5.5 Summary and conclusions; References; 6 Dynamics of Wall-Bounded Turbulence; 6.1 Introduction; 6.2 The classical theory of wall-bounded turbulence; 6.3 The dynamics of the near-wall region; 6.4 The logarithmic and outer layers; 6.5 Coherent structures and dynamical systems; 6.6 Conclusions; References; 7 Recent Progress in Stratified Turbulence; 7.1 Introduction; 7.2 Scaling, cascade and spectra

7.3 Numerical simulations7.4 Laboratory experiments; 7.5 Field data; 7.6 Conclusions; Appendix; References; 8 Rapidly-Rotating Turbulence: An Experimental Perspective; 8.1 The evidence of the early experiments; 8.2 Background: inertial waves and the formation of Taylorcolumns; 8.3 The spontaneous growth of Taylor columns fromcompact eddies at low Ro; 8.4 Anisotropic structuring via nonlinear wave interactions:resonant triads; 8.5 Recent experimental evidence on inertial waves andcolumnar vortex formation; 8.6 The cyclone-anticyclone asymmetry: speculative cartoons

8.7 The rate of energy decay8.8 Concluding remarks; References; 9 MHD Dynamos and Turbulence; 9.1 Introduction; 9.2 Dynamo; 9.3 Mean field; 9.4 Conclusions; References; 10 How Similar is Quantum Turbulence to Classical Turbulence?; 10.1 Introduction; 10.2 Preliminary remarks on decaying QT; 10.3 Comparisons between QT and HIT: energy spectrum; 10.4 Decaying vorticity; 10.5 Decay of HIT when the shape of the energy spectramatters; 10.6 Effective viscosity; 10.7 Conclusions; References

Leading experts summarize our current understanding of the fundamental nature of turbulence, covering a wide range of topics.

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