1. Thermophysical and transport fundamentals. 2. Boundary Layers. 3. External laminar flow: Similarity solutions for forced laminar boundary layers. 4. Internal laminar flow. 5. Integral methods. 6. Fundamentals of turbulence and external turbulent flow. 7. Turbulent and transitional internal flow. 8. Effect of transpiration on friction, heat, and mass transfer. 9. Analogy among momentum, heat, and mass transfer. 10. Natural Convection. 11. Mixed Convection. 12. Turbulence Models. 13. Flow and heat transfer in miniature flow passages. 14. Diffusion and convective transport of particles. Appendix A. Constitutive relations in polar cylindrical and spherical coordinates. Appendix B. Mass continuity and Newtonian incompressible fluid equations of motion in polar cylindrical and spherical coordinates. Appendix C. Energy conservation equations in polar cylindrical and spherical coordinates for incompressible fluids with constant thermal conductivity. Appendix D. Mass species conservation equations in polar cylindrical and spherical coordinates for incompressible fluids. Appendix E. Thermodynamic properties of saturated water and steam. Appendix F. Transport properties of saturated water and steam. Appendix G. Properties of selected ideal gases at 1 atm. Appendix H. Binary diffusion coefficients of selected gases in air at 1 atmosphere. Appendix I. Henry’s constant (in bars) for dilute aqueous solutions of selected substances at moderate pressures. Appendix J. Diffusion coefficients of selected substances in water at infinite dilution at 25°C. Appendix K. Lennard–Jones potential 6–12 model constants for selected molecules. Appendix L. Collision integrals for the Lennard–Jones 6–12 potential model. Appendix M. Some RANS-type turbulence models. Appendix N. Physical constants. Appendix O. Unit conversions. Appendix P. Summary of important dimensionless numbers. Appendix Q. Summary of some useful heat transfer and friction factor correlations.
Biography
S. Mostafa Ghiaasiaan is a professor in the George W. Woodruff School of Mechanical Engineering at the Georgia Institute of Technology, USA. After earning a PhD in thermal science from the University of California, Los Angeles in 1983, he worked in the aerospace industry for eight years, conducting research and development activity on modeling and simulation of transport processes, multiphase flow, and thermal–hydraulic aspects of nuclear power. He joined the faculty at the Georgia Institute of Technology in 1991. Prof. Ghiaasiaan has written more than 240 publications on transport phenomena, multiphase flow, cryogenics and the science and technology of cryocoolers. He is a fellow of the American Society of Mechanical Engineers and a registered professional mechanical engineer in California, and a member of American Nuclear Society and Cryogenics Society of America. He is also the author of another widely-used graduate textbook on two-phase flow, boiling and condensation.
