Implicit Large Eddy Simulation
Computing Turbulent Fluid Dynamics

This book describes a tecnique for numerical simulation of turbulent flows, Implicit Large Eddy Simulation (ILES).

Fernando F. Grinstein (Edited by), Len G. Margolin (Edited by), William J. Rider (Edited by)

9780521869829, Cambridge University Press

Hardback, published 30 July 2007

578 pages
25.4 x 17.8 x 3.2 cm, 1.21 kg

"... a well-coordinated text presenting a coherent view of this promising tool...a timely addition to the reference on turbulence simulation and modeling. It provides a significant step forward within the large eddy simulation community in the discussion of ILES. I recommend the book highly to researchers in the field..."
Gregory A. Blaisdell, Purdue University for AIAA Journal

The numerical simulation of turbulent flows is a subject of great practical importance to scientists and engineers. The difficulty in achieving predictive simulations is perhaps best illustrated by the wide range of approaches that have been developed and are still being used by the turbulence modeling community. In this book the authors describe one of these approaches, Implicit Large Eddy Simulation (ILES). ILES is a relatively new approach that combines generality and computational efficiency with documented success in many areas of complex fluid flow. This book synthesizes the theoretical basis of the ILES methodology and reviews its accomplishments. ILES pioneers and lead researchers combine here their experience to present a comprehensive description of the methodology. This book should be of fundamental interest to graduate students, basic research scientists, as well as professionals involved in the design and analysis of complex turbulent flows.

Introduction Fernando Grinstein, Len Margolin and William Rider
Part I. Motivation: 1. Historical introduction Jay Boris
2. ILES for turbulent flows: a rationale Fernando Grinstein, Len Margolin and William Rider
Part II. Capturing Physics with Numerics: 3. Subgrid scale modeling: issues and approaches Pierre Sagaut
4. Numerics for ILES
4a. Limiting algorithms Dimitris Drikakis, Marco Hahn, Fernando Grinstein, Carl DeVore, Christer Fureby, Mattias Liefvendahl and David Youngs
4b. Piecewise parabolic method Paul Woodward
4c. Lagrangean remap method David Youngs
4d. MPDATA Piotr Smolarkiewicz and Len Margolin
4e. Vorticity confinement John Steinhoff, Nicholas Lynn and Lesong Wang
5. Numerical regularization Len Margolin and William Rider
6. Approximate deconvolution Nikolaus Adams and J. A. Domaradzki
Part III. Verification and Validation: 7. Homogeneous turbulence David Porter and Paul Woodward
8. Vortex dynamics and transition in free shear flows Fernando Grinstein
9. Symmetry bifurcation and instabilities Dimitris Drikakis
10. Incompressible wall bounded flows Christer Fureby, Mattias Liefvendahl, Urban Svennberg, Leif Persson and Tobias Persson
11. Compressible turbulent shear flows Christer Fureby and Doyle Knight
12. Studies based on vorticity confinement John Steinhoff, Nicholas Lynn, Wenren Yonghu, Meng Fan, Lesong Wang and Bill Dietz
13. Rayleigh-Taylor and Richtmyer-Meshkov mixing David Youngs
Part IV. Frontier Flows: 14. Studies of geophysics Piotr Smolarkiewicz and Len Margolin
15. Studies of astrophysics David Porter and Paul Woodward
16. Complex engineering turbulent flows Niklas Alin, Magnus Berglund, Christer Fureby, Eric Lillberg and Urban Svennberg
17. Large scale urban simulations Gopal Patnaik, Fernando Grinstein, Jay Boris, Ted Young and Oskar Parmhed
18. Outlook and open research issues Fernando Grinstein, Len Margolin and William Rider.

Subject Areas: Mechanics of solids [TGMD], Mechanical engineering [TGB]