| Center |
| Student Information Service-Master |
| Departament |
| Earth Physics and Thermodynamics |
| Lecturers in charge |
| Sin datos cargados |
| Met. Docent |
| Mixed traditional approach and work by groups with public presentation by the groups of the material developed by them. Written report by pairs of students of a specific subject (optional). |
| Met. Avaluació |
| Individual exam and group project work (public presentation of the project) |
| Bibliografia |
| J. Spurk, Fluid Mechanics, Springer, 1997 J. Spurk, Fluid Mechanics, Problems and Solutions, Springer, 1997 J. A. Ligget, Fluid Mechanics, McGraw-Hill, 1994 G. K. Batchelor, Introduction to Fluid Dynamics, Cambridge University Press, 1987 L. D. Landau y E. M. Lifshitz, Fluid Mechanics, Pergamon, 1987 (Hay traducción al castellano de la edición anterior de editorial Reverté, tomo 6 del Curso de Física Teórica). G.K. Batchelor, An Introduction to Fluid Dynamics, Cambridge University Press 2000 D.J. Acheson, Elementary Fluid Dynamics, Clarendon Press, 1990 A. J. Chorin y J. E. Marsden, A Mathematical Introduction to Fluid Mechanics, 3ª ed, Springer 2000 D. S. Chandrasekhariah y L. Debnath, Continuum Mechanics, Academic 1994 |
| Continguts |
| 1.Kinematics 1.1 The continuuum hypothesis 1.2 Lagrangian and Eulerian descriptions. 1.3 Substantial derivative. 1.4 Equations of continuity. 1.5 Flow velocity of given expansion rate and vorticity. 2. Dynamics 2.1 Conservation of mass. 2.2 Balance of momentum. 2.3 Balance of angular momentum. 2.4 Non-inertial frames of reference. 2.5 Balance of energy. 2.6 Balance of entropy. 2.7 The stress tensor. 3. Equations of motion. 3.1 The Navier-Stokes equations. 3.2 Vorticity equation. 3.3 Couette and Poiseuille flow. 3.4 Adimensional numbers: the Reynolds number. 3.5 The law of similarity. 4. Inviscid fluids 4.1 Euler's equations 4.2 Bernuill's equation. 4.3 Irrotational flow 4.4 Kelvin's theorem. 5. Stokes flow 5.1 Viscous flows. 5.2 Stokes equation. 5.3 Flow in porous media. 5.4 Flow in thin films 5.5 Hele-Shaw flow. 6. Boundary layer theory 6.1 Prandtl's boundary layer approach of Navier-Stokes equations 6.2 Boundary layer thickness 6.3 Separation. 6.4 The temperature boundary layer. 7. Turbulent flow 7.1 Methods of analysis in turbulence. 7.2 Turbulent diffusivity. 7.3 Hypothesis of homogeneous and isotropic turbulence. 7.4 Mean value equations of motion: Reynolds stress. 7.5 Heat transfer in turbulent flow: the equation of the energy in average values. 7.6 Turbulent flow near a wall: the law of Prandtl. 7.7 Logarithmic velocity profile. |
| Objetius |
| It is a basic course on the physics of fluids (PoF). The PoF includes the convective term in the equation of motion, effects of viscosity of the fluid and important non-linear phenomena like turbulence, and the objective of the course is both to familiarize the student with the physics of fluids, and to allow he/she to deepen later on the PoF. |
| URL de Fitxa |
| http://www.uv.es/~acv/privadodocent/Fis.Fluidos/ |