Table of Contents

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.