MATHEMATICAL PHYSICS

MATHEMATICAL PHYSICS FOR B.Sc. PROGRAMMES

FIRST YEAR COURSES

COMMON COURSE

The First Year common programme in Mathematical Physics consists of the modules MP110 and MP112. There are three formal lectures per week throughout the year. In addition there is one tutorial per week throughout both semesters. There are two three hour examination papers in the examination period. Continuous assessment of the modules may count for up to 15% of the first year mark applied to the student’s advantage.

MP110 MECHANICS I & SPECIAL RELATIVITY

36 lecture hours

7.5 ECTS credits

Linear kinematics and dynamics of a particle and of a system of particles. Principles of momentum and energy. Particle dynamics in more than one dimension. Vector methods. Motion in a circle, simple harmonic motion, motion under constant gravity.

Introduction to special relativity: Postulates of special relativity, spacetime, time dilation, length contraction, Doppler shift.

MP112 MECHANICS 2 & MODERN PHYSICS

36 lecture hours

7.5 ECTS credits

Centre of mass and moment of inertia. Two dimensional dynamics of a system of particles, including collision and impulse. Motion of a rigid body. Two dimensional statics - friction problems, frameworks and virtual work. Motion under a central force. Vector analysis and some potential theory.

Quantum Physics: Photoelectric effect, blackbody radiation, wave-particle duality, Heisenberg uncertainty principle.

Bachelor of Science (Theoretical Physics and Computer Science).

MH205

First Year Courses

Mathematical Physics, Computer Science, Mathematics and Experimental Physics.

MATHEMATICAL PHYSICS FOR HONOURS THEORETICAL PHYSICS AND MATHEMATICS DEGREE
MH206

First Year Courses

Double Mathematical Physics and Double Mathematics.

DOUBLE MATHEMATICAL PHYSICS COURSE

The First Year Double Mathematical Physics programme for the Theoretical Physics and Mathematics course is listed below.

There are six formal lectures and two tutorials per week. There are three 3 hour examination papers in the Examination period. Students take the modules MP110, MP112, MP120, MP201 and MP202. Continuous assessment of the modules may count for up to 15% of the first year mark applied to the student’s advantage.

MP120 MATHEMATICAL PHYSICS

24 lecture hours

5 ECTS credits

Differential Equations: First order equations and integrating factors, second order, linear equations with constant coefficients.

Mechanics: Newton's second law as differential equation, variable mass problems.

Thermodynamics: Kinetic theory of gases, Maxwell-Boltzmann distribution, temperature, ideal gases, entropy and free energy, first and second laws of thermodynamics.

SECOND YEAR COURSES

COMMON COURSE

The modules for the Second Year Mathematical Physics course are listed below. There are four lectures and two tutorials per week. There are two 3 hour examination papers in the Examination period. Continuous assessment of the modules may count for up to 15% of the second year mark applied to the student’s advantage.

MP201 MATHEMATICAL METHODS

24 lecture hours

5 ECTS credits

Introduction to partial derivatives. Integrals: surface, volume, line. Gauss's and Stokes's theorems. Orthogonal expansions. Fourier Series. Calculus of variations.

MP202 MECHANICS

24 lecture hours

5 ECTS credits

Motion of a particle in one dimension. Motion in a resisting medium. Damped harmonic oscillator. Forced damped harmonic oscillator. Equations of motion of a particle in two or three dimensions. Projectiles under resistance. The Kepler problem. Motion of a system of particles. Rigid body motion in two dimensions. Lagrange's equations. Hamilton's equations. Wave theory.

MP231 ELECTRICITY AND MAGNETISM I

24 lecture hours

5 ECTS credits

Electrostatic field, charge, potential and flux. Gauss's and Stokes's theorems. Capacitance. Dielectrics and polarisation. Energy of an electric field. magnetic effects of currents.

MP232 ELECTRICITY & MAGNETISM 2 AND STATISTICAL THERMODYNAMICS

24 lecture hours

5 ECTS credits

Magnetostatic field. Magnetic vector potential. The Biot-Savart law. Mutual and self

induction. Magnetic materials. Ampere's law. Magnetic energy. Uniqueness of solution of

potential problems and the method of images. Neumann and Lenz's laws of induction.

Maxwell equations.

The Boltzmann distribution and macroscopic thermodynamics. The equipartition theorem and the ideal gas equation. Quantum statistical mechanics. Applications to specific heats. Ideal particles. Fermi-Dirac and Bose-Einstein distributions. Planck's radiation law.

Bachelor of Science (Theoretical Physics and Computer Science).

MH205

Second Year Courses

Mathematical Physics, Computer Science and Mathematics.

MATHEMATICAL PHYSICS FOR HONOURS THEORETICAL PHYSICS AND MATHEMATICS DEGREE
MH206

Second Year Courses
The modules offered are the same as in the third year of the Honours Mathematical Physics Programme (see below).

THIRD YEAR COURSES

GENERAL COURSE

The Third Year General programme in Mathematical Physics consists of the following set of modules: MP350, MP352, MP353 and MP354. There are four lectures and two tutorials per week. In addition there is a two hour laboratory per week for one semester in connection with MP354. There are two three hour examination papers in the Examination period. Continuous assessment of MP354 counts for up to 15% of the overall third year mark in Mathematical Physics.

HONOURS COURSE

There are six lectures and two tutorials per week. In addition there is two hours laboratory work for one semester which is associated with MP354. There are three 3 hour examination papers in the Examination period. Continuous assessment of MP354 counts for up to 15% of the overall third year honours mark in Mathematical Physics. 50% of the third year result will be carried over to the final year Double Honours Degree in Mathematical Physics applicable to the students’ advantage. 35% of the third year result will be carried over to the final year Single Honours Degree in Theoretical Physics applicable to the students advantage.

MP350 CLASSICAL MECHANICS

24 lecture hours

5 ECTS credits

Lagrange theory. Variational principles. Hamilton's Principle.

Lagrange equations. Lagrange multipliers. Central forces. Two-body motion: bound states.

Rigid Body Motion. Euler's theorem. Euler's equation of motion. The heavy symmetrical

top. Small oscillations Hamiltonian theory. The canonical equations.

Canonical transformations. Generating functions. Poisson brackets.

Hamilton-Jacobi theory: The Hamilton-Jacobi equation. Action-angle variables.

MP352 SPECIAL RELATIVITY

24 lecture hours

5 ECTS credits

Inertial frames. Michelson-Morley and Fizeau experiments. Stellar aberration. Principle of

special relativity and Lorentz transformations. Length contraction and time dilatation.

Relativistic mechanics. Particle collisions, centre of mass systems and threshold energies.

Covariance of electromagnetic field equations and their covariant formalism. Tensors.

MP353 FLUID MECHANICS

24 lecture hours

5 ECTS credits

Kinematics of fluid motion. Euler's equations, steady flow. Bernoulli's equation. Circulation.

Kelvin's theorem. Velocity potential for two and three dimensional flows. Sources, sinks

and doublets. The complex potential. Method of images. Vortex lines. Supersonic flow.

Viscosity. Viscous flow. Navier Stokes' equation. Reynold's number. Turbulence.

Poiseuille flow. Couette flow. Kolmogorov Scaling.

MP354 COMPUTATIONAL PHYSICS I

12 lecture hours + 24 laboratory hours

5 ECTS credits

Each Lecture is followed by 2 hours laboratory work

Introduction to Unix. Introduction to C. Error, accuracy and stability.

Integration. Root finding. Newton-Raphson. Ordinary Differential Equations:

Euler method. Runge-Kutta method.

MP361 MATHEMATICAL METHODS I

24 lecture hours

5 ECTS credits

Calculus in several variables. Linear differential equations with constant and variable coefficients.

Construction of Green's functions. Solution by power series, including treatment of singular points.

Legendre, Laguerre, Hermite and Bessel polynomials. Fourier Series. Boundary value problems in

one variable.

MP362 MATHEMATICAL METHODS 2

24 lecture hours

5 ECTS credits

Sturm-Liouville theory and expansion in orthogonal bases. Fourier and Laplace transforms. Partial Differential equations: Heat equation, Wave equation, Laplace's equation. Spherical harmonics. Green's functions for boundary value problems.Complex analysis up to Cauchy's residue theorem.

Bachelor of Science (Theoretical Physics and Computer Science).

MH205

Third Year Courses

Double Honours Mathematical Physics and Double Honours Computer Science.

MATHEMATICAL PHYSICS FOR HONOURS THEORETICAL PHYSICS AND MATHEMATICS DEGREE

MH206

Third Year Courses
The modules offered are the same as in the 4th year of the Double Honours Mathematical Physics Degree (see below)

FOURTH YEAR COURSES

HONOURS COURSE

The modules for the final year Single Honours course in Theoretical Physics and the Double Honours course in Mathematical Physics are listed below.

For the Single Honours course in Theoretical Physics students take all the listed modules. There are 12 lectures and four tutorials per week. In addition for one semester there are two hours laboratory work per week and project work associated with module MP468. There are 5 three hour written examination papers at the end of the second semester. Continuous assessment and project work associated with MP468 will count for up to 15% of the fourth year mark in Theoretical Physics. The final degree result will be based on 65% of the fourth year result plus 35% of the third year result. The latter is applied to the student's advantage.

Double Honours students in Mathematical Physics take modules (a) MP462 and MP463 plus optional modules from the following groups of modules which add up to 20 ECTS. (b) MP460 and MP461 (10 ECTS), (c) MP464 and MP465 (10 ECTS), (d) MP466 and MP467 (10 ECTS) and (e) MP468 and MP470 (20 ECTS). The final degree result in Mathematical Physics will be based on 50% of the fourth year mark plus 50% of the third year mark. The latter is applied to the students advantage.

MP460 THERMODYNAMICS

24 lecture hours

5 ECTS credits

0th law of thermodynamics (definition of temperature).

Ideal gas law, kinetic theory of gases, Van der Waal's equation.

Maxwell-Boltzmann distribution.

1st law of thermodynamics.

2nd law of thermodynamics, (Carnot cycles, entropy, Boltzmann's H-theorem).

3rd law of thermodynamics.

Thermodynamic functions (Helmholz and Gibb's functions).

Legendre transforms (Gibb's surfaces, Gibb's rule of phases, Gibbs-Duhem relation).

Maxwell's equations.

MP461 STATISTICAL MECHANICS

24 lecture hours

5 ECTS credits

Partition functions (simple sub-systems, ideal gas, simple solids, ferro-magnet, Ising

model). Micro-canonical and grand canonical ensembles. Phase transitions and critical phenomena. Bose-Einstein and Fermi-Dirac statistics. Bose-Einstein condensation (super-conductors and super-fluids). Information theoretic approach to entropy and partition function.

MP462 QUANTUM MECHANICS I

24 lecture hours

5 ECTS credits

Stern-Gerlach Experiments

Rotation of Basis States and Matrix Mechanics

Angular Momentum

Time Evolution

A System of Two Spin-2 Particles. Bell Inequalities.

MP463 QUANTUM MECHANICS 2

24 lecture hours

5 ECTS credits

Wave Mechanics in One Dimension

The One-Dimensional Harmonic Oscillator

Translational and Rotational Symmetry in the Two-Body Problem

Bound States of Central Potentials

Perturbation Theory

MP464 SOLID STATE PHYSICS

24 lecture hours

5 ECTS credits

Crystal Structure

Free Electron Theory of Metals

Energy Bands

Semiconductors

Diamagnetism and Paramagnetism

MP465 ELECTROMAGNETISM

24 lecture hours

5 ECTS credits

Review of Maxwell Equations in vacuo

Scalar and vector potentials

Multipole expansions in electrostatics

Multipole expansions in magnetostatics

Dielectrics

Diamagnetism and Paramagnetism

Maxwell's Equations in ponderable media

Waveguides

Radiation from simple systems: multipole expansions and energy transport

Co-variant formalism of electromagnetism, gauge invariance

MP466 PARTICLE PHYSICS

24 lecture hours

5 ECTS credits

Introduction to Forces and Particles

The four forces; classification of leptons, hadrons, mesons,

baryons; strangeness, gravitons

The Quark model:

Quark model of mesons and baryons; charm (J/Psi); QCD;

asymptotic freedom

Electro-weak theory

Isospin; neutrinos; Higg's bosons; electro-weak interactions;

neutrino masses

Symmetries

Conservation laws; discrete symmetries (CPT); C, P and T violation

(K_L-K_S oscillations)

Grand Unification:

Grand unification; proton decay; super-symmetry

Current developments:

Elementary discussion of string theory, current topics

MP467 COSMOLOGY

24 lecture hours

5 ECTS credits

Star Formation:

Jean's mass; PP-chain and CNO-cycle.

Stellar Structure:

Hydro-static equilibrium; radiation transport; Eddington limit

Degenerate Stars:

Super-novae; white dwarves; neutron stars; pulsars; black-holes

Binary systems:

Gravitational radiation

Galactic structure and evolution:

Active galactic nuclei; radio galaxies; quasars

Cosmology:

Big Bang; micro-wave background radiation; cosmological constant;

nucleo-synthesis; inflation

Astro-particle physics:

Cosmic rays; monopoles; dark matter

MP468 COMPUTATIONAL PHYSICS II

12 lecture hours + 24 hours laboratory + 20 hours project work

12 ECTS credits

Partial Differential Equations. Elliptic equations - Laplace's equation. Hyperbolic equations

Wave equations. Parabolic equations - Diffusion. Conservative methods - continuity

equation. Matrix eigenvalue problems - Schroedinger equation. Monte Carlo Methods and

Simulation - random number generators, integration, Metropolis algorithm.

MP470 CHAOS, NONLINEAR DYNAMICS & QUANTUM INFORMATION PROCESSING

36 lecture hours

8 ECTS credits

Fixed points, limit cycles and strange attractors.

Iterated maps.

Quadratic maps: Period doubling, Quasi periodicity, devil's staircase, Farey tree.

Universality. Intermittency route to chaos.

Hamiltonian systems.

Lyapunov exponents, Kolmogorov- Sinai entropy.Concept of Dimension. Fractals

and multifractals.

Fundamental Concepts of Quantum Information processing.

Introduction to Quantum Mechanics

Introduction to computer science

Quantum Circuits

Quantum Fourier Transform and its applications

Quantum search algorithm

Physical realisations of quantum information processors

Bachelor of Science (Theoretical Physics and Computer Science).

MH205

Fourth Year Courses

Double Honours Mathematical Physics and Double Honours Computer Science.

MATHEMATICAL PHYSICS FOR B.A. PROGRAMMES

FIRST YEAR COURSES

COMMON/GENERAL COURSE

MP110 MECHANICS I & SPECIAL RELATIVITY

36 lecture hours

7.5 ECTS credits

Introduction to special relativity: Postulates of special relativity, spacetime, time dilation, length contraction, Doppler shift.

MP112 MECHANICS 2 & MODERN PHYSICS

36 lecture hours

7.5 ECTS credits

Quantum Physics: Photoelectric effect, blackbody radiation, wave-particle duality, Heisenberg uncertainty principle.

HONOURS COURSE

The first year Honours Mathematical Physics programme consists of four lectures and two tutorials per week. Students take MP110, MP112, MP120.

DOUBLE MATHEMATICAL PHYSICS FOR THE BA HONOURS

MATHEMATICAL SCIENCE COURSE

The First Year Double Mathematical Physics programme for the Mathematical Science course is listed below.

MP120 MATHEMATICAL PHYSICS

24 lecture hours

5 ECTS credits

Differential Equations: First order equations and integrating factors, second order, linear equations with constant coefficients.

Mechanics: Newton's second law as differential equation, variable mass problems.

Thermodynamics: Kinetic theory of gases, Maxwell-Boltzmann distribution, temperature, ideal gases, entropy and free energy, first and second laws of thermodynamics.

SECOND YEAR COURSES

COMMON/GENERAL COURSE

MP201 MATHEMATICAL METHODS

24 lecture hours

5 ECTS credits

Introduction to partial derivatives. Integrals: surface, volume, line. Gauss's and Stokes's theorems. Orthogonal expansions. Fourier Series. Calculus of variations.

MP202 MECHANICS

24 lecture hours

5 ECTS credits

MP231 ELECTRICITY AND MAGNETISM I

24 lecture hours

5 ECTS credits

Electrostatic field, charge, potential and flux. Gauss's and Stokes's theorems. Capacitance. Dielectrics and polarisation. Energy of an electric field. magnetic effects of currents.

MP232 ELECTRICITY & MAGNETISM 2 AND STATISTICAL THERMODYNAMICS

24 lecture hours

5 ECTS credits

Magnetostatic field. Magnetic vector potential. The Biot-Savart law. Mutual and self

induction. Magnetic materials. Ampere's law. Magnetic energy. Uniqueness of solution of

potential problems and the method of images. Neumann and Lenz's laws of induction.

Maxwell equations.

THIRD YEAR COURSES

THIRD YEAR BA GENERAL MATHEMATICAL PHYSICS COURSE

SECOND YEAR BA MATHEMATICAL PHYSICS COURSE

SECOND YEAR BA MATHEMATICAL SCIENCE COURSE

MP350 CLASSICAL MECHANICS

24 lecture hours

5 ECTS credits

Lagrange theory. Variational principles. Hamilton's Principle.

Lagrange equations. Lagrange multipliers. Central forces. Two-body motion: bound states.

Rigid Body Motion. Euler's theorem. Euler's equation of motion. The heavy symmetrical

top. Small oscillations Hamiltonian theory. The canonical equations.

Canonical transformations. Generating functions. Poisson brackets.

Hamilton-Jacobi theory: The Hamilton-Jacobi equation. Action-angle variables.

MP352 SPECIAL RELATIVITY

24 lecture hours

5 ECTS credits

Inertial frames. Michelson-Morley and Fizeau experiments. Stellar aberration. Principle of

special relativity and Lorentz transformations. Length contraction and time dilatation.

Relativistic mechanics. Particle collisions, centre of mass systems and threshold energies.

Covariance of electromagnetic field equations and their covariant formalism. Tensors.

MP353 FLUID MECHANICS

24 lecture hours

5 ECTS credits

Kinematics of fluid motion. Euler's equations, steady flow. Bernoulli's equation. Circulation.

Kelvin's theorem. Velocity potential for two and three dimensional flows. Sources, sinks

and doublets. The complex potential. Method of images. Vortex lines. Supersonic flow.

Viscosity. Viscous flow. Navier Stokes' equation. Reynold's number. Turbulence.

Poiseuille flow. Couette flow. Kolmogorov Scaling.

MP354 COMPUTATIONAL PHYSICS I

12 lecture hours + 24 laboratory hours

5 ECTS credits

Each Lecture is followed by 2 hours laboratory work

Introduction to Unix. Introduction to C. Error, accuracy and stability.

Integration. Root finding. Newton-Raphson. Ordinary Differential Equations:

Euler method. Runge-Kutta method.

MP361 MATHEMATICAL METHODS I

24 lecture hours

5 ECTS credits

Calculus in several variables. Linear differential equations with constant and variable coefficients.

Construction of Green's functions. Solution by power series, including treatment of singular points.

Legendre, Laguerre, Hermite and Bessel polynomials. Fourier Series. Boundary value problems in

one variable.

MP362 MATHEMATICAL METHODS 2

24 lecture hours

5 ECTS credits

THIRD YEAR BA SINGLE HONOURS THEORETICAL PHYSICS COURSE

THIRD YEAR BA DOUBLE HONOURS MATHEMATICAL PHYSICS COURSE

THIRD YEAR BA HONOURS MATHEMATICAL SCIENCE COURSE

FOURTH YEAR COURSES

HONOURS COURSE

The modules for the final year Single Honours course in Theoretical Physics and the Double Honours course in Mathematical Physics are listed below.

MP460 THERMODYNAMICS

24 lecture hours

5 ECTS credits

0th law of thermodynamics (definition of temperature).

Ideal gas law, kinetic theory of gases, Van der Waal's equation.

Maxwell-Boltzmann distribution.

1st law of thermodynamics.

2nd law of thermodynamics, (Carnot cycles, entropy, Boltzmann's H-theorem).

3rd law of thermodynamics.

Thermodynamic functions (Helmholz and Gibb's functions).

Legendre transforms (Gibb's surfaces, Gibb's rule of phases, Gibbs-Duhem relation).

Maxwell's equations.

MP461 STATISTICAL MECHANICS

24 lecture hours

5 ECTS credits

Partition functions (simple sub-systems, ideal gas, simple solids, ferro-magnet, Ising

MP462 QUANTUM MECHANICS I

24 lecture hours

5 ECTS credits

Stern-Gerlach Experiments

Rotation of Basis States and Matrix Mechanics

Angular Momentum

Time Evolution

A System of Two Spin-2 Particles. Bell Inequalities.

MP463 QUANTUM MECHANICS 2

24 lecture hours

5 ECTS credits

Wave Mechanics in One Dimension

The One-Dimensional Harmonic Oscillator

Translational and Rotational Symmetry in the Two-Body Problem

Bound States of Central Potentials

Perturbation Theory

MP464 SOLID STATE PHYSICS

24 lecture hours

5 ECTS credits

Crystal Structure

Free Electron Theory of Metals

Energy Bands

Semiconductors

Diamagnetism and Paramagnetism

MP465 ELECTROMAGNETISM

24 lecture hours

5 ECTS credits

Review of Maxwell Equations in vacuo

Scalar and vector potentials

Multipole expansions in electrostatics

Multipole expansions in magnetostatics

Dielectrics

Diamagnetism and Paramagnetism

Maxwell's Equations in ponderable media

Waveguides

Radiation from simple systems: multipole expansions and energy transport

Co-variant formalism of electromagnetism, gauge invariance

MP466 PARTICLE PHYSICS

24 lecture hours

5 ECTS credits

Introduction to Forces and Particles

The four forces; classification of leptons, hadrons, mesons,

baryons; strangeness, gravitons

The Quark model:

Quark model of mesons and baryons; charm (J/Psi); QCD;

asymptotic freedom

Electro-weak theory

Isospin; neutrinos; Higg's bosons; electro-weak interactions;

neutrino masses

Symmetries

Conservation laws; discrete symmetries (CPT); C, P and T violation

(K_L-K_S oscillations)

Grand Unification:

Grand unification; proton decay; super-symmetry

Current developments:

Elementary discussion of string theory, current topics

MP467 COSMOLOGY

24 lecture hours

5 ECTS credits

Star Formation:

Jean's mass; PP-chain and CNO-cycle.

Stellar Structure:

Hydro-static equilibrium; radiation transport; Eddington limit

Degenerate Stars:

Super-novae; white dwarves; neutron stars; pulsars; black-holes

Binary systems:

Gravitational radiation

Galactic structure and evolution:

Active galactic nuclei; radio galaxies; quasars

Cosmology:

Big Bang; micro-wave background radiation; cosmological constant;

nucleo-synthesis; inflation

Astro-particle physics:

Cosmic rays; monopoles; dark matter

MP468 COMPUTATIONAL PHYSICS II

12 lecture hours + 24 hours laboratory + 20 hours project work

12 ECTS credits

Partial Differential Equations. Elliptic equations - Laplace's equation. Hyperbolic equations

Wave equations. Parabolic equations - Diffusion. Conservative methods - continuity

equation. Matrix eigenvalue problems - Schroedinger equation. Monte Carlo Methods and

Simulation - random number generators, integration, Metropolis algorithm.

MP470 CHAOS, NONLINEAR DYNAMICS & QUANTUM INFORMATION PROCESSING

36 lecture hours

8 ECTS credits

Fixed points, limit cycles and strange attractors.

Iterated maps.

Quadratic maps: Period doubling, Quasi periodicity, devil's staircase, Farey tree.

Universality. Intermittency route to chaos.

Hamiltonian systems.

Lyapunov exponents, Kolmogorov- Sinai entropy.Concept of Dimension. Fractals

and multifractals.

Fundamental Concepts of Quantum Information processing.

Introduction to Quantum Mechanics

Introduction to computer science

Quantum Circuits

Quantum Fourier Transform and its applications

Quantum search algorithm

Physical realisations of quantum information processors

This is a course of study ending in a substantial dissertation in a branch of Mathematical Physics, making a significant original contribution to the subject. The research topic will be chosen from one of the areas of expertise within the Department.

Relativistic quantum field theory, general relativity, quantum gravity, renormalization group, gauge theory, application of topology in physics, nonlinear physics, dynamical systems, classical and quantum chaos, low dimensional systems, fractals, nonlinear-optics/photonics and computational physics.

Minimum requirement II₁ honours degree. (Normally a first class honours degree is required.)

Application forms may be obtained from the Registrar's Office or directly from the Secretary of the Department. Applicants should talk to the Head or a member of the Department before applying.

One can pursue a masters degree in Mathematical Physics or Mathematical Science by research (dissertation) or a combination of course work and research (lectures/dissertation).

Students who perform well may, at the discretion of the Head of Department, transfer to the Ph.D programme.

Application forms may be obtained from the Registrar's Office or directly from the Secretary of the Department. Applicants should talk to the Head or a member of the Department before applying.

Students take courses in Mathematical Physics and/or Mathematics. The courses taken by a student will be determined in consultation with the Head of Department.

Assessment is by continuous assessment and written examination. Some of these requirements may, in consultation with the head of Department, be satisfied by the submission of a thesis on an area of Mathematical Physics or Mathematics.

Based on the performance in the Degree, students may be allowed to proceed to study for a Ph.D. subject to the availability of places and the approval of the Head of Department.

Higher Diploma in Mathematical Science
This one year course is intended for graduates holding a primary degree in which mathematical physics formed a substantial part (for example, a B.E., a B.A. (Gen) or B.Sc. (Gen) which included mathematical physics). It involves a course of lectures in Mathematical Physics, together with a minor project whose emphasis is on the practical and modern applications of the subject.

The Higher Diploma in Mathematical Science is a one year full-time honours postgraduate diploma course.

There are 12 lectures, 3 tutorials and 2 hours laboratory per week. Students take modules MP350 (Classical Mechanics), MP354 (Computational Physics I), MP361 (Mathematical Methods I), MP362 (Mathematical Methods 2), MP352 (Special Relativity), MP353 (Fluid Mechanics), and modules up to 30 ECTS credits from MP460 (Thermodynamics), MP461 (Statistical Physics), MP462 (Quantum Mechanics I), MP463 (Quantum Mechanics 2), MP464 (Solid State Physics), MP465 (Electromagnetism), MP466 (Particle Physics), MP467 (Cosmology), MP468 (Computational Physics II), MP470 (Chaos, Nonlinear Dynamics and Quantum Information Processing).

In the examination period, there are six three-hour examination papers. The continuous assessment of the Computational Physics courses counts for up to 15% of the overall degree mark.

The course involves extensive computer simulation (modelling) of physical and engineering systems.

The course is open to graduates holding a primary degree in which Mathematical Physics formed a substantial component (e.g. B.Sc. (General) or B.A. (General) including Mathematical Physics, or B.E.), subject to the approval of the Head of Department.

Candidates who obtain a II₁ honours may transfer to the M.Sc. programme subject to the availability of places and the approval of the Head of Department.

Application forms may be obtained from the Registrar's Office or directly from the Secretary of the Department. Applicants should talk to the Head or a member of the Department before applying.