TY - BOOK AU - Gatski,T.B. AU - Bonnet,Jean-Paul TI - Compressibility, turbulence and high speed flow SN - 9780123970275 U1 - 532.0527015118 22 PY - 2013/// CY - Amsterdam, Boston PB - Academic Press KW - Turbulence KW - Mathematical models KW - Compressibility KW - fast N1 - Includes bibliographical references and index; 1; Kinematics, Thermodynamics and Fluid Transport Properties; 1 --; 1.1; Kinematic Preliminaries; 4 --; 1.1.1; Motion of Material Elements; 5 --; 1.1.2; Deformation; 6 --; 1.1.3; Reynolds Transport Theorem; 10 --; 1.2; Equilibrium Thermodynamics; 11 --; 1.3; Compressible Subsonic and Supersonic Flows; 14 --; 1.4; Turbulent Flows and Compressible Turbulence; 18 --; 2; Compressible Flow Dynamics; 23 --; 2.1; Mass Conservation; 23 --; 2.2; Momentum Conservation; 24 --; 2.2.1; Surface Forces: The Stress Tensor; 26 --; 2.2.2; Body Forces; 28 --; 2.3; Energy Conservation; 28 --; 2.4; Solenoidal Velocity Fields and Density Changes; 32 --; 2.5; Two-Dimensional Flow and a Reynolds Analogy; 36 --; 3; Compressible Turbulent Flow; 39 --; 3.1; Averaged and Filtered Variables; 39 --; 3.1.1; Reynolds Average; 40 --; 3.1.2; Average Over Fixed Phase; 41 --; 3.1.3; Temporal LES Filters; 42 --; 3.1.4; Spatial LES Filters; 43 --; 3.2; Density-Weighted Variables; 44 --; 3.3; Transport Equations for the Mean/Resolved Field; 51 --; 3.4; Fluctuation Transport Equations; 59 --; 3.5; Momentum and Thermal Flux Relationships; 64 --; 3.5.1; Strong Reynolds Analogy; 64 --; 3.5.2; Morkovin's Hypothesis; 75 --; 4; Experimental Measurement and Analysis Strategies; 79 --; 4.1; Experimental Constraints for Supersonic Flows; 80 --; 4.1.1; Constraints on Wind Tunnel Testing; 80 --; 4.1.2; Constraints on Data Collection and Measurement Apparatus; 84 --; 4.2; Measurement Methods; 88 --; 4.2.1; Intrusive Method: Hot-Wire Anemometry; 89 --; 4.2.2; Non-Intrusive Methods; 96 --; 4.3; Analysis Using Modal Representations; 106 --; 4.4; Reynolds-and Favre-Averaged Correlations; 114 --; 5; Prediction Strategies and Closure Models; 117 --; 5.1; Direct Numerical Simulations; 118 --; 5.1.1; Homogeneous Turbulence; 118 --; 5.1.2; Homogeneous Sheared Turbulence; 121 --; 5.1.3; Inhomogeneous Sheared Turbulence; 123 --; 5.2; Large Eddy Simulations and Hybrid Methods; 124 --; 5.3; Reynolds-Averaged Navier-Stokes Formulation; 130 --; 5.3.1; Turbulent Stress and Stress Anisotropy; 131 --; 5.3.2; Turbulent Energy Dissipation Rate; 137 --; 5.3.3; Velocity-Pressure Gradient Correlation; 150 --; 5.3.4; Scalar Fluxes and Variances; 159 --; 5.3.5; Other Closure Issues; 165 --; 6; Compressible Shear Layers; 169 --; 6.1; Jets; 170 --; 6.2; Mixing-Layers; 174 --; 6.2.1; Flow Structure; 175 --; 6.2.2; Spreading Rate; 182 --; 6.3; Wakes; 194 --; 6.3.1; Base Flows; 195 --; 6.3.2; Flat Plate Wakes; 198 --; 6.4; Boundary Layers; 199 --; 6.4.1; Inner Layer: Mean Field Structure; 203 --; 6.4.2; Outer Layer: Law of the Wake; 211 --; 6.4.3; Integral Parameters; 213 --; 6.4.4; Turbulent Field; 221 --; 7; Shock and Turbulence Interactions; 231 --; 7.1; Homogeneous Turbulence Interactions; 231 --; 7.1.1; Application of Linear Theory; 232 --; 7.1.2; Numerical Simulations; 239 --; 7.1.3; Experiments; 245 --; 7.2; Inhomogeneous Turbulence Interactions; 253 --; 7.2.1; Free Shear Flows; 253 --; 7.2.2; Wall-Bounded Flows; 258 --; 8; Elements of Compressible Flow Control; 271 --; 8.1; Characteristic Features; 272 --; 8.1.1; Scaling Effects; 272 --; 8.1.2; High Speed Effects of Actuators; 273 --; 8.2; Actuators; 277 --; 8.2.1; Control jets Issuing from Fluidic Actuators; 277 --; 8.2.2; Energy Deposition Type Actuators; 279 --; 8.2.3; Surface Plasma Actuators; 281 --; 8.3; Shear Flow Control; 282 --; 8.3.1; Jets and Mixing-Layers; 283 --; 8.3.2; Cavity Flows; 286 --; 8.3.3; Flows with Shocks; 288 ER -