Physics with Mathematics (MPhys)

Beginning with a review of Newton's Laws applied to systems of particles, the course moves on to rotational motion, dynamical gravity (Kepler's Laws) and motion in non-inertial reference frames. Systems of coupled oscillators are studied.

Electromagnetism is one of the brilliant successes of nineteenth century physics and the equations formulated by Maxwell are believed to account exactly for all classical electromagnetic phenomena. The aim of this course is to present the laws of elect...

Differential equations occupy a central role in mathematics because they allow us to describe a wide variety of real-world systems. The module will aim to stress the importance of both theory and applications of differential equations. The module begin...

The PHYS2022 Physics from Evidence I module consists of three parts: Teaching Lab, Computing Module and Student Conference. The Teaching Lab and Computing Modules run through the first 10 weeks of the semester and the Student Conference is in week 12.

After studying this course students should be able to explain the concept of quantum mechanical wave function and its basic properties, the Schrödinger equation, the concepts of operator, eigenstates and the significance of measurements, and describe the ...

Statistical mechanics links the microscopic properties of physical systems to their macroscopic properties. Thermodynamics, which describes macroscopic properties, can then be derived from statistical mechanics with a few well motivated postulates. It lea...

In the first part of this module we build on multivariate calculus studied in the first year and extend it to the calculus of scalar and vector functions of several variables. Line, surface and volume integrals are considered and a number of theorems inv...

This course introduces the properties and mechanics of waves, from the derivation and solution of wave equations, through the origins of the classical processes of refraction, dispersion and interference, to the quantum mechanical phenomenon of the uncert...

The aim of this course is to apply quantum physics to the study of atoms.

This Computational Physics course is designed for students with definite interest in tackling physics problems that are only tractable through the use of computers. It covers all types of application of computers by physicists, except the control of equip...

This course builds upon the Statistical Mechanics Course (PHYS2024) to form a complete basic course on the fundamentals of the physics of solids. After the course the student should have developed the necessary theoretical knowledge to enable them to unde...

The first part of the course is devoted to exploring a given topic via group work, assessed via short, written summary (extended abstract) and oral presentation. The second part consists of an individual dissertation that is assessed via a written report...

Students will learn about Nuclear Scattering, various properties of Nuclei, the Liquid Drop Model and the Shell Model, radioactive decay, fission and fusion. By the end of the course, the students should be able to classify elementary particles into hadro...

Introduce the students to the practical application of a relatively wide spectrum of numerical techniques and familiarise the students with numerical coding. Often in mathematics, it is possible to prove the existence of a solution to a given problem, ...

A wide variety of physics topics is covered, showing the experimental evidence underlying a number of topics in physics encountered in lecture courses and textbooks. Students are also introduced to techniques they might encounter in a physics-related care...

This is a module principally on Einstein's general theory of relativity, a relativistic theory of gravitation which explains gravitational effects as coming from the curvature of space-time. It provides a comprehensive introduction to material which is cu...

Variational methods in classical physics will be reviewed and the extension of these ideas in quantum mechanics will be introduced.

General relativity is the theory of spacetime and gravity developed by Einstein. This module aims to develop a geometric understanding of general relativity and explore advanced applications of GR. In particular, we will study the physics of black holes (...

Students in the synoptic exam will be expected to display a broad knowledge and understanding of the core first, second and third year courses, to understand the inter-relations between those courses and to display problem solving skills in novel problem ...

In this module, students undertake a research project which extends over both semesters of the final year. Students normally work in pairs, in close collaboration with a member of staff.

The emphasis of this module is on the methods required to develop mathematical models using differential equations to understand physical problems. The module involves both conventional lectures as well as discussion lectures. The discussion lectures comp...

This course will cover advanced topics of quantum mechanics including postulates of quantum mechanics, tools of quantum mechanics, Dirac notation, Simple Harmonic oscillator (studied using raising and lowering operators), orbital and spin angular momentum...

Modern cosmology is a fascinating and fast-developing field, with intense research activity fuelled by major discoveries made in the last decade. These have overturned our understanding of the Universe’s properties and established a new standard cosmologi...

This module is designed for MMath and MPhys students in their fourth year, and builds directly upon MATH3006 Relativity, Blackholes and Cosmology. Gravitational waves are tiny ripples in space-time, first predicted by Einstein himself in 1916. These ...

Lasers and photonic techniques are used in all branches of science and technology. The principles of laser operation will be discussed, with reference to commonly used laser systems. The course provides knowledge of the laser as a fundamental tool of cont...

The course provides an introduction to modern optical physics to arm students with a basic knowledge of light-matter interactions, electro-optics and nonlinear optics. It aims to provide a fundamental base for understanding the techniques and technologies...

The main radiation mechanisms are discussed and examples are given of the situations in which they are most important. We show how the physical conditions, e.g. the temperature, density and magnetic field strength, can be determined from the emitted radia...

Since the end of the 1990s, cosmology has experienced one of the most impressive advances among all scientific disciplines. This happened mainly because of astonishing progress in the precision and accuracy of astronomical and cosmological observations ...

The upper atmosphere consists of the outermost layers of Earth's atmosphere, above about 90 km altitude, on the edge of space. It is a very different place to the atmosphere we live in at ground level; temperatures reach extremes of cold (< 200 K) and ext...

Quantum information combines information science with quantum effects in physics to study of how to process and transmit information using quantum systems. This includes quantum computation, quantum teleportation and quantum cryptography. Quantum metrol...

While coherence phenomena have long been familiar in the context of light waves, their manifestation in the context of matter waves is an exciting development of modern quantum science. This course aims to introduce the basic concepts needed to understand...