PX285 Hamiltonian and Fluid Mechanics
Lecturer: Tony Arber
Weighting: 15 CATS
This module looks at the Hamiltonian and Lagrangian formulation of classical mechanics and introduces the mechanics of fluids. Lagrangian and Hamiltonian mechanics have provided the natural framework for several important developments in theoretical physics including quantum mechanics.
The field of fluids is one of the richest and most easily appreciated in physics. Tidal waves, cloud formation and the weather generally are some of the more spectacular phenomena encountered in fluids. The module establishes the basic equations of motion for a fluid - the Navier-Stokes equations - and shows that in many cases they can yield simple and intuitively appealing explanations of fluid flows.
Aims:
To revise the key elements of Newtonian mechanics and use this to develop Lagrangian and Hamiltonian mechanics. The module should also explain why PDEs (with associated boundary conditions) are an appropriate model for fluids. The module should prepare students for future applied mathematics modules.
Objectives:
At the end of the module you should be able to
- Recognise and write down the equations of motion for incompressible fluids (the Navier- Stokes equations) and understand the origin and physical meaning of the various terms including the boundary conditions
- Derive Poiseuille's formula and understand the conditions for it to be a valid description of fluid flow
- Use dimensional analysis to analyse fluid flows. In particular, you should appreciate the relevance of the Reynolds number.
- Simplify the equations of motion in the case of incompressible irrotational flow and solve them for simple cases including vortices
- Explain the boundary layer concept
Syllabus:
Hamiltonian and Lagrangian Mechanics: Analogy with optics and constructive interference; principle of least action; examples of Euler Lagrange Equations. 1-D trajectory, T-V case, worked examples; T+V as a constant of the motion; multiple coordinates with examples. Generalised coordinates and canonical momenta. Polar coordinates; angular momentum; moment of inertia of rigid bodies; treatment of constraints. Symmetry and Conservation Laws. Hamiltonian formulation. Hamilton's equations, phase space, examples. Normal Modes and Small Oscillations. Inertial and stiffness matrices, diatomic and triatomic molecules.
Fluids: Materials which do not support shear. Idea of a Newtonian fluid. Plausibility of τ = μ ∂u/∂y from assumption of a relaxation time for stress. Hydrostatics, forces due to pressure and gravity. Hydrodynamics: acceleration, continuity and incompressibility. Euler equation. Streamlines: Integrating Euler for steady flow along a streamline to give Bernoulli. Energy considerations. Applications of Bernoulli: flux through a hole, Pitot-static tube, aerofoil, waves on shallow water. Hydrodynamics of Viscous Flow: Forces due to viscosity, Navier-Stokes equation. Poiseuille formula for laminar flow between plates. Turbulence, role of Reynolds number. Physical interpretation of Re as Inertial forces/Viscous forces. Irrotational Flow: Definition of vorticity and circulation, Kelvin's circulation theorem. Uniform flow, flow past a cylinder. Lift on thin aerofoil, as example for Magnus Effect. Circulation around a cylinder. Vortices. Advection of unlike vortices. The vortex ring. Circling of like vortices. Vortices at edges of wings. Real Flows: Idea of boundary layer; Boundary layer separation and drag crisis.
Commitment: about 18 Lectures
Assessment: 1 hour examination
This module has a home page.
Recommended Texts: H Goldstein, Classical Mechanics; A helpful reference for the beginning of the module is: Feynmann, Leighton & Sands, The Feynmann Lectures on Physics, Vol 2, Chapter 19
LD Landau and EM Lifshitz, Fluid Mechanics, Pergamon; DJ Tritton, Physical Fluid Dynamics, OUP; TE Faber Fluid Dynamics for Physicists, CUP