MMath Mathematics with Financial Mathematics

This unit describes the fundamental theory of continuum mechanics in a unified mathematical framework. The unit will cover the formulation of governing conservation and balance laws in generalised coordinates in both Eulerian and Lagrangian viewpoints. Specific examples of constitutive modelling will be developed via the theories of nonlinear and linear elasticity together with those of compressible and incompressible fluid mechanics.

Students are not permitted to take, for credit, MATH45061 in an undergraduate programme and then MATH65061 in a postgraduate programme at the University of Manchester, as the courses are identical.

The course unit concerns the formulation and solution of problems in continuum mechanics (solid and fluid mechanics)  from a modern unified perspective. The aims are (i) to introduce students to the general analytic machinery of tensor calculus, variational principles and conservation laws in order to formulate governing equations; (ii) to illustrate the principles of constitutive modelling; and (iii) to make students aware of some exact, approximate and numerical methods to solve the resulting equations.

On successful completion of this course unit students will be able to: 

• Use tensor algebra and calculus for calculations and derivations in general (curvilinear) coordinates.
• Derive the governing equations of continuum mechanics from Lagrangian and Eulerian viewpoints using the divergence and Reynolds transport theorems and use the same principles to extend the derivations to previously unseen situations.
• Determine whether particular vectors, tensors and derivatives are objective and explain the concept of objectivity.
• Use the Clausis-Duhem inequality to derive thermodynamically consistent constitutive laws and determine any implied constraints.
• Use the general theory to formulate and solve problems in linear and nonlinear elasticity and compressible and incompressible fluid mechanics.
• Solve idealised problems in continuum mechanics analytically in spherical, cylindrical and Cartesian coordinates.
• Be able to convert the physical description of a problem in continuum mechanics into the appropriate governing equations and boundary conditions and, conversely, provide a physical interpretation for the solutions.

Tutorials represent the principal forum for feedback, providing an opportunity for students' work on example sheet questions and the coursework to be discussed. There are two coursework assignments in the form of extended calculations that both test understanding and provide opportunities for further feedback. Students can also get feedback on their understanding directly from the lecturer by making an appointment, for example during the lecturer's office hours.