The final year in Nottingham is also tailored to you as an individual, using a range of key modules that have not been studied during the year abroad. The final major element is a research project in a specific area of cutting-edge physics.
To develop an understanding of high-energy phenomena in astrophysics and the relative importance of different processes in different situations.
To make models of extreme astrophysical sources and environments basedon physical theory.
To interpret observational data in the light of relevant physical theory.
Functional Medical Imaging
The techniques for magnetic resonance imaging (MRI) and spectroscopy (MRS) are explored. The course aims to introduce the brain imaging technique of functional magnetic resonance imaging (fMRI), giving an overview of the physics involved in this technique. The electromagnetic techniques of electroencephalography (EEG) and magnetoencephalography (MEG) will then be outlined, and the relative advantages of the techniques described.
This module introduces you to the physical properties of semiconductors and low-dimensional systems, such as quantum wells, wires and dots. The aim is to explain the physics that underlies optical and transport properties of these structures and and their applications in advanced technologies.
This course is structured in two main parts. The first part focuses on the foundation of quantum mechanics and solid state physics needed to describe a low dimensional system. The module then moves on describing the physical principles of semiconductor junction and devices.
This module aims to provide you with the skills necessary to use computational methods in the solution of non-trivial problems in physics and astronomy. You’ll also sharpen your programming skills through a three hour computing class and one hour of lectures per week.
Nonlinear Dynamics and Chaos
In this module you will develop your knowledge of classical mechanics of simple linear behaviour to include the behaviour of complex nonlinear dynamics. You’ll learn about the way in which nonlinear deterministic systems can exhibit essentially random behaviour because of sensitivity relating to initial conditions. You’ll have two hours per week of lectures studying this module.
Atmospheric and Planetary Physics
In this module you’ll explore the theoretical aspect of atmospheric physics. Topics will include planetary atmosphere, troposphere, solar radiation and the Energy budget, radiation transfer and Photochemistry among others. You’ll have two hours of lectures per week studying this module.
Symmetry and Action Principles in Physics
Symmetry is a powerful notion, both in the development of theories of physical phenomena and in the solution of physical models. In this module, the basic aspects of the mathematical language of symmetry will be introduced and applied to a range of physical phenomena, and the principle of least action, introduced in The Principles of Dynamics module, will be further developed.
Theoretical Elementary Particle Physics
To introduce the key theoretical ideas of elementary particle physics, such as symmetry and conservation laws, and to build the foundations for a mathematical description of particle properties and interactions.
Introduction to Cosmology
Cosmology is the scientific study of the universe as a whole. The module provides an introduction to modern cosmology, including some of the more recent observational and theoretical developments. No prior knowledge of General Relativity is required. Topics covered include: observed features of the universe, the Cosmological Principle, Newtoniaan and Relativistic cosmology, the Friedmann Models, cosmic expansion, the cosmological constant, evidence for the big bang model, the thermal history of the big bang, the early universe and inflation, the classical cosmological tests, structure formation (brief treatment only).
Enterprise for Chemists
Students will learn about the factors that lead to successful innovation, including evaluation and management of an idea/concept.
In addition, students will consider the factors required to extract the value from a product/concept (e.g. market awareness) and the potential routes to market available from both an academic and industrial viewpoint.
The Structure of Stars
You will develop your knowledge of the various physical processes occurring in stars of different types. You’ll use this knowledge to build both mathematical models and your qualitative physical understanding of stellar structure and evolution will be enhanced. You’ll have two hours per week of lectures studying this module.
The Structure of Galaxies
This module will develop your current understanding of the various physical processes that dictate the formation, evolution and structure of galaxies. You’ll explore a number of topics including The Milky Way, The Dynamics of Galaxies, Active Galaxies and Galaxy Evolution among others. You’ll spend two hours per week in lectures studying this module.
Force and Function at the Nanoscale
You’ll be given an overview of how forces at the nanoscale are different to those observed in macroscopic systems and will consider how they can be exploited in nanometre-scale processes and devices.
You’ll focus on the physical basis and measurement of forces operating on the nanoscale, considering van der Waals, electrostatic, hydrophobic and hydrophilic interactions.
You’ll spend around three hours per week in lectures and workshops studying this module.
Principles of Dynamics
In this module you’ll be introduced to the mathematical language for discussing extreme problems. The formulations of mechanics due to Lagrange and Hamilton will be described and techniques for the solutions of the consequent equations of motion will be discussed. You’ll learn the underlying principles of dynamics and develop techniques for the solution of dynamical problems. You’ll have two hours per week of lectures studying this module.
Theory Toolbox will enhance your knowledge of the principles of theoretical physics and your understanding of the analytical methods for the analysis of physical problems.
You’ll extend and develop your knowledge of quantum theory with a particular emphasis on how quantum systems evolve over time. The module will focus on developing the mathematical formalism of quantum mechanics as well as introducing important physical models and calculational techniques.