Theory and Computation in Hydrodynamic Stability

W. O. Criminale is Professor Emeritus in the Department of Applied Mathematics at the University of Washington. His research focuses on the areas of initial-value problems in shear flows, large-scale oscillations in turbulent flows, mixing, and nonlinear mechanics. Professor Criminale is the recipient of many honors, which include: the Alexander von Humboldt Senior Research Award; Fellow, American Physical Society; Guest Scientist, Stanford–Ames Turbulence Research Center; the Faculty Research Award, Battelle Pacific Northwest Laboratories; and Royal Society Fellow in the UK. T. L. Jackson is a Research Professor in the Department of Mechanical and Aerospace Engineering at the University of Florida. He is currently a Fellow of American Physical Society (APS), an Associate Fellow of American Institute of Aeronautics and Astronautics (AIAA), a member of the Combustion Institute and a member of American Society of Mechanical Engineers (ASME). He was previously an Associate Editor for the AIAA Journal, and he currently serves on the Editorial Advisory Board for the Journal of Propulsion and Power. His expertise is in the area of basic fluid mechanics, combustion, stability, solid propellant combustion, energetic material modeling and the large-scale simulation thereof. R. D. Joslin is a permanent Program Director in the Engineering Directorate at the US National Science Foundation in Alexandria, Virginia. He manages the Fluid Dynamics Program and other cross-Foundation programs. Dr Joslin was previously a Program Manager at the Office of Naval Research, where he managed the Turbulence, Stratified Wakes, Submarine Maneuvering, Ocean Energy, Multi-Platform Interactions and Supercaviation Programs. He is a member of the American Physical Society (APS), American Society of Mechanical Engineers (ASME) and is an Associate Fellow in the American Institute of Aeronautics and Astronautics (AIAA). His areas of expertise include fundamental fluid mechanics, turbulence and transition, stability theory, DNS/LES/CFD, supercavitation and renewable energy.

1. Introduction and problem formulation; 2. Temporal stability of inviscid incompressible flows; 3. Temporal stability of viscous incompressible flows; 4. Spatial stability of incompressible flows; 5. Stability of compressible flows; 6. Centrifugal stability; 7. Geophysical flow; 8. Transient dynamics; 9. Nonlinear stability; 10. Transition and receptivity; 11. Direct numerical simulation; 12. Flow control and optimization; 13. Investigating hydrodynamic instabilities with experiments; Appendix A. Mathematical formulas; Appendix B. Numerical methods; Appendix C. Solutions to exercises; References; Author index; Subject index.