Computational Physics MPhys

The close relationship between physics and high-performance computing worldwide is embodied in the Computational Physics degree programme.<br/><br/>Most theoretical problems are now sufficiently complex that they cannot be solved by mathematics alone. <br/><br/>As experimentation becomes more difficult and expensive, computer simulation has become established as the most practical way to understand complex phenomena such as: <br/><br/><br/>* turbulence <br/><br/><br/>* nuclear reactors and weapons <br/><br/><br/>* climate change <br/><br/><br/>These are the areas where computational physicists already dominate. In the future, based on current recruitment patterns, the methods of Computational Physics will also come to dominate other areas such as: <br/><br/><br/>* financial markets <br/><br/><br/>* genomics <br/><br/><br/>* disease control <br/><br/><br/>This physics-based programme is for students interested in computing, modelling and simulation. You will study: <br/><br/><br/>* programming <br/><br/><br/>* algorithms <br/><br/><br/>* problem-solving methodologies <br/><br/><br/>You will receive a thorough education in physics and the associated mathematics, together with the ability to write computer programs to simulate natural systems. <br/><br/>This degree programme includes substantial practical experience and the opportunity to use the Universitys world-class computing systems.