Pure and Applied Physics

Delivered through lectures, problem-based learning and laboratory sessions, in this module you will be introduced to the following subjects: classical dynamics, static and dynamic charges, fundamentals of quantum mechanics, fundamentals of relativity and atomic and nuclear physics.

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Delivered through key note lectures, tutorial and problem-based learning classes and practical laboratory sessions, in this module you will be introduced to the following subjects: thermodynamics, microscopic and macroscopic properties of matter, fundamentals of waves and geometrical optics and wave optics.

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Being able to apply your scientific knowledge and thinking to unfamiliar problems is a key skill for success in industry and research. By introducing you to this skill, along with other important skills identified by our industrial and academic partners, they will become second nature, giving you a head start in your chosen career.

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Delivered through key note lectures, tutorial and problem-based learning classes and practical laboratory sessions, in this module you will be introduced to the following subjects: operational principles of electrical and electronic circuits, fundamentals of digital electronics, and principles of optoelectronics.

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This module will review A level mathematics, with additional tutorials and support, covering the following subjects: algebra, trigonometry, functions, geometry, vectors, complex numbers and calculus, with emphasis on their applications to physics.

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Using computer aided learning and extra tutorials this module will improve your knowledge of differential equations and series with emphasis on their applications to physics and develop your awareness of the importance of mathematics in a quantitative description of physics. You will be introduced to the use of spreadsheets, computing programming and symbolic computing.

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The fundamentals of vibrations and waves apply across a wide range of systems. In this module you will develop an understanding of the effects of damping and forcing on vibrations, and of coupled systems. You will learn to develop expressions for velocities of mechanical waves in various systems, and be introduced to a number of characteristic wave phenomena, such as standing waves, beats, wave packets, Doppler effect and the effects of boundaries on wave propagation and reflection.

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This module will introduce the concepts and nature of heat energy and its analysis. The subjects covered include: microscopic description of ideal and non ideal gases, pressure and molecular motion, velocity distribution functions and the Maxwell Boltzman speed distribution function, energy distribution functions, transport phenomena, mean free paths and random walks, and the classical and quantum theory of cavity radiation.

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Continuing from year 1 mathematics, this module deepens your understanding and skills for the mathematical modelling of physics. You will learn to use mathematical tools such as vector calculus and matrices to identify and solve physically-based problems. Examples of subjects included are: divergence theorem and Stokes' theorem, special matrices and matrix inversion. eigenvalues and eigenvectors and solutions of Partial Differential Equations.

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Computer programming skills are very useful for the physicist, not only in research but also in industry. You will build on your introduction to programming from the first year, applying programming to computational physics problems and analysis.

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Through one laboratory session per week in the first semester, supported by academics and technical staff, you will widen and deepen your understanding and practice of good experimental and analytical technique, physical principles associated with physics and good report writing skills, learning more advanced experimental procedure and data analysis.

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From sunglasses to fibre optics and lasers, this module will teach you the tools to understand and analyse the behaviour of light. The course includes geometric optics, polarisation, scattering of light by objects, interference and coherence and simple lasers.

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This module will introduce the concepts of magnetic field and magnetic flux related to current flow, the laws of Ampere and Faraday and some applications, basic properties of magnetic material and provide a basic understanding of alternating current behaviour.

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In this module you will widen and deepen your understanding of the nature of matter at an atomistic level. Subjects included are: amorphous solids, quantum numbers, radial probability distribution function of s and p orbital's, crystal defects (introduction to point, line and planar defects) electrical conduction in metals transport processes in liquids, viscous flow and turbulence

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An introduction to the world of quantum mechanics will be delivered in this module. You will develop both a quantitative and qualitative understanding of the principles of quantum mechanics. Subjects include wave particle duality, development of the Schroedinger wave equation, quantum tunnelling, and angular momentum and spin.

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In this module you will work on project-based experiments, allowing you to extend your knowledge acquisition and analytical techniques, and learn more about team working within the context of scientific research.

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This module will provide a broad spectrum instruction to the many aspects of astrophysics including: astronomical coordinate systems, telescopes, orbital mechanics, planetary atmospheres, nuclear reactions within stars, small solar system bodies and galactic structure.

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You will learn how to use MATLAB software for the computer simulation of complex systems. These systems include nonlinear maps logistic and Ricker maps (population modelling) the Lorenz equations (atmospheric turbulence and convection) Maxwell-Bloch equations (dynamics of semiconductor lasers). You'll also do a group project from a list that includes quantifying chaos and fractality, optical switching in laser cavities and chaos in spatially-extended systems.

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PC interfacing is a useful skill for any physicist, allowing you to interface measurement and control systems. In this module you will be introduced to the basic principles of microcomputer interfacing, microcomputer architecture and to the main analogue and digital interface devices.

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One of the most important parts of the preparation for your future career, whether in industry, research or even education, is the undertaking of a final year project. The projects can be chosen from a list provided by an academic or on a subject of your choice, if agreed by a supervising academic.

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In this module you will be provided with an overview of nuclear physics, an understanding of nuclear stability in terms of the liquid drop model, of nuclear reactions involving neutrons, protons, electrons and neutrinos, and major experimental techniques and practical applications. The particle physics aspects of the module will cover the basic discoveries of modern particle physics and introduce the ideas of grand unified theory.

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Maxwell's equations and their applications will be introduced to you in this module along with an understanding of electromagnetic (e.m.) wave behaviour at interfaces and the energy carried by the e.m. field. Subjects included are Stokes' and Gauss' theorems, Biot Savart law, time dependent e.m. effects and Poynting's vector.

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This module will build on your knowledge from quantum mechanics 1 furthering your understanding of approximation techniques in quantum mechanics, the interaction of radiation with particles and of scattering phenomena. Subjects include stationary state perturbation theory, the Zeeman effect, the Stark effect, energy time uncertainty, induced and spontaneous emission, and the Born approximation.

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Along with quantum mechanics, relativity is one of the great paradigm shifts of the 20th century. In this module you will develop familiarity with Einstein's special theory of relativity, and understand the role played by relativity theory in a modern understanding of quantum mechanics and electromagnetism. Subjects include special relativity, relativity in quantum mechanics and relativistic electromagnetism.

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Semi-conductors are the foundations of modern technology, much of which we use in our everyday lives. This module will provide knowledge of the behaviour of electrons in metals and semiconductors, and allow you to perform calculations of solid state parameters. Subjects include: free electron model of solids quantum theory leading to Fermi energy, density of states, and the thermoelectric and Hall effects.

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Building on your knowledge from the Introductory Optics module, you will learn to use Fourier optics as a technique for analysing diffractive limits on imaging and how standard Fourier pairs are used to obtain important results in the diffractive theory of imaging. The subjects include Fourier transforms in two and three dimensions, Fraunhofer diffraction, Abbe sine theory and holography.

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The astrophysics part to this module will concentrate on the nature of stars from the nuclear physics in energy generation in to spectral classification, luminosities, and the Hertzsprung-Russell diagram. The discovery of the muon and pion, hadrons, baryons and mesons, strangeness and its conservation and quarks and charmed particles are just a few of the subjects covered in the particle physics part of the module.

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Strange things happen at low temperatures. In this module you will develop an understanding of physics at very low temperatures, including the phenomena of superfluidity and superconductivity. The subjects include theories of Helium: London, Landau and Feynman, Fermi-Dirac systems, properties of the superfluid phase, superconductivity, Meissner effect, and methods of attaining and measuring low temperatures.

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