Module Code
PHY1001
Physics studies how our Universe works. It includes areas such as quantum theory, relativity and particle physics, and lies at the heart of most modern technology - for example the computer and the laser. Most forefront science takes place in international collaborations, and this 5-year MSci degree includes a year studying abroad. It is aimed at students who wish to continue Spanish beyond school.
Students undertaking the Physics with Spanish degree will spend a year studying physics in a university in Spain.
Accredited by the Institute of Physics for the purpose of exemptions from some professional examinations. Support for this international placement can be sought during the degree through an application to the Turing programme.
You will be taught in our new state-of-the-art teaching centre, containing specialist laboratory equipment and computer facilities. Students also use some of the research facilities in their final year projects, such as a telescope observatory on the roof of the main building, one of the most powerful university lasers in the world, and state-of-the-art nano-fabrication and characterisation facilities.
All of our faculty staff are research scientists in their own right; in the 2021 REF peer-review exercise, Physics Research Power was in the top 20 in the UK.
In the 2023 National Student Survey physics scored above the benchmark in 6 out of 7 themes with a 94.9% positivity score on how well staff explained things.
You can join the Physics and Mathematics Society (PAMSOC) which organises events and trips throughout the year. You can also take advantage of the many events held within the Northern Ireland Science Festival each February, which School staff and postgraduate students heavily support. Many of our students also support other students by becoming peer mentors which qualifies them for the enhanced Degree Plus award.
The most recent HESA data shows that over 95% of QUB physics graduates are in employment or further study 15 months after graduation.
The School has the 3rd highest postgraduate research student satisfaction in the University.
The School of Mathematics and Physics was 3rd of 15 schools in the University in overall NSS score.
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Course content
The course unit details given are subject to change, and are the latest example of the curriculum available on this course of study.
In their first year students study a core of experimental, theoretical and computational physics, alongside applied mathematics (all compulsory modules).
At Stage 2, students take 6 compulsory modules
Advanced laboratory work develops the skills of planning, carrying out and analysing experiments and simulations, and provides opportunities for deepening understanding of the wide applicability of physics.
Students will take an approved Turing programme of study at a Spanish speaking university or alternatively, an approved placement in a Spanish speaking country.
At Stage 4, a choice of modules is made to develop in-depth understanding.
At Stage 5, specialist modules are available, broadly reflecting research interests of those teaching in the Department.
Also in this year, a major project is carried out in association with one of these research areas, with the student working within world-leading research groups. Through this project students gain an intensive insight into modern scientific research.
Students can also undertake projects with an outside organisation or company, provided the research is approved by the Director of Education. Some projects may result in publications in national and international scientific journals.
School of Maths & Physics
Dr Kar is a Reader in Physics and is an internationally recognised expert in the areas of high-intensity laser-plasma interaction. His main focus is on the development and optimisation of laser-driven ion and neutron sources for their wide-ranging applications in Science, security and healthcare.
9 (hours maximum)
9 hours of lectures.
6 (hours maximum)
6 hours of practical classes and computer workshops each week in Level 1, increasing to an average of 8 hours of practical work per week in Level 2.
2 (hours maximum)
2 hours of tutorials (or later, project supervision) each week.
16 (hours maximum)
14-16 hours studying and revising in your own time each week, including some guided study using handouts, online activities, homeworks etc.
At Queen’s, we aim to deliver a high quality learning environment that embeds intellectual curiosity, innovation and best practice in learning, teaching and student support to enable students to achieve their full academic potential. Examples of the opportunities provided for learning on this degree programme are:
Information associated with lectures and assignments is often communicated via a Virtual Learning Environment (VLE) called Canvas. A range of e-learning experiences are also embedded in the degree programme through the use of, for example, interactive support materials and web-based learning activities.
As physics is an experimentally based subject, all students will undertake experimental physics as part of their degree. Students normally work in assigned pairs in the laboratory, with submitted reports and findings individually assessed. As part of this work students will become proficient in using Excel for analysing data and Word for laboratory reports. In their final year students will undertake a final year project, placed within one of our international research centres in Physics.
These introduce and explain the foundation information about topics as a starting point for further self-directed private study/reading. The material in the lectures will follow the syllabus issued at the start of the module, and will form the basis of the assessment carried out. As the modules progress and students' knowledge of physics grows, this information becomes more complex. Lectures, which are normally delivered in large groups to all year-group peers, also provide opportunities to ask questions and seek clarification on key issues as well as gain feedback and advice on assessments.
Additional lectures may also be also delivered by invited speakers and scientists from various areas of physics – these lectures generally do not form part of the assessed work, but students are encouraged to attend to widen their knowledge and appreciation of the subject. There may also be lectures from employers of physics graduates. These enable employers to impart their valuable experience to physics students, and allows our physics students to meet and engage with potential future employers.
This is an essential part of life as a Queen’s student when important private reading, engagement with e-learning resources, reflection on feedback to date and assignment research and preparation work is carried out.
A significant amount of teaching is carried out in small groups (2–5 students), particularly at Stage 1. These sessions are designed to explore, in more depth, the information that has been presented in the lectures, and are normally based on coursework submitted by the students. This provides students with the opportunity to engage closely with academic staff who have specialist knowledge of the topic, to ask questions of them and to assess their own progress and understanding with the support of their peers. During these classes, students will be expected to present their work to academic staff and their peers.
The way in which students are assessed will vary according to the learning objectives of each module. Details of how each module is assessed are shown in the Student Handbook which may be accessed online via the School website. Physics modules are typically assessed by a combination of continuous assessment and a final written unseen examination. Continuous assessment consists of:
As students progress through their course at Queen’s they will receive general and specific feedback about their work from a variety of sources including lecturers, module coordinators, personal tutors, advisers of study and peers (other students). University students are expected to engage with reflective practice and to use this approach to improve the quality of their work. Feedback may be provided in a variety of forms including:
Undergraduate Teaching Centre
Throughout their time with us, students will use the new Mathematics and Physics Teaching Centre. Opened in 2016 with almost £2 million of new equipment, students can use the well-equipped twin computer rooms for both self-study and project work. In the physics laboratories, students will be able to investigate everything from the nature of lasers, to the quantum mechanical properties of the electron, to the dynamic hydrogen chromosphere of the Sun.
The study of physics is the study of the particles and forces that make our world. It’s fantastic to take students on a journey in their degree from their studies at school through to the very edge of our understanding about our Universe.
Alan Fitzsimmons (Professor of Astronomy)
The information below is intended as an example only, featuring module details for the current year of study (2024/25). Modules are reviewed on an annual basis and may be subject to future changes – revised details will be published through Programme Specifications ahead of each academic year.
Classical Mechanics:
Newton’s Laws, Elasticity, Simple Harmonic Motion, Damped, Forced and Coupled Oscillations, Two- Body Dynamics, Centre of Mass, Reduced Mass, Collisions, Rotational Motion, Torque, Angular Momentum, Moment of Inertia, Central Forces, Gravitation, Kepler’s Laws
Special Relativity:
Lorentz Transformations, Length Contraction and Time Dilation, Paradoxes, Velocity Transformations, Relativistic Energy and Momentum
Waves:
Wave Equation, Travelling Waves, Superposition, Interference, Beats, Standing Waves, Dispersive Waves, Group Velocity, Doppler Effect
Electricity and Magnetism:
Static electric and magnetic fields. Time varying magnetic fields and motional emf. Electrical circuit analysis including dc and ac theory and circuit transients
Light and Optics:
Electromagnetic waves, dispersion by prisms and diffraction gratings, interference, diffraction, polarization, X-rays.
Quantum Theory:
Wave-particle duality, photoelectric effect, Bohr model, spectra of simple atoms, radioactive decay, fission and fusion, fundamental forces and the Standard Model.
Thermodynamics:
Kinetic theory of gases, Van der Waal’s equation, first and second laws of thermodynamics, internal energy, heat capacity, entropy. Thermodynamic engines, Carnot cycle. Changes of state.
Solid State:
Solids, crystal structure, bonding and potentials, thermal expansion. Introduction to band structure of metals, insulators and semiconductors. Origin and behaviour of electric and magnetic dipoles.
Demonstrate knowledge and conceptual understanding in the areas of classical mechanics, special relativity, waves and oscillations, electricity and magnetism, light and optics, quantum theory, thermodynamics, and solid state, by describing, discussing and illustrating key concepts and principles.
Solve problems by identifying relevant principles and formulating them with basic mathematical relations.
Perform quantitative estimates of physical parameters within an order of magnitude.
Problem solving. Searching for and evaluating information from a range of sources. Communicating scientific concepts in a clear and concise manner both orally and in written form. Working independently and with a group of peers. Time management and the ability to meet deadlines.
Coursework
10%
Examination
60%
Practical
30%
40
PHY1001
Full Year
24 weeks
Course contents:
This module aims to consolidate and expand on existing Spanish language competency by developing written and oral language skills, knowledge of Spanish and Latin American culture, and grammatical proficiency, to equip students with professional and employability skills in preparation for further study of Spanish. It consists of four elements designed to provide a comprehensive consolidation of Spanish language competence:
1. Language Seminar (1hr per week)
Seminar aims to develop students’ ability to understand, translate, and compose Spanish-language materials in a range of forms: text, image, audio-visual. Language will be engaged in context, guided by themes such as University Life, Culture & Identity, and Culture & Communication. Linguistic competence will be developed through a range of methods that may include: group discussion, translation, responsive and report writing.
2. Grammar Workshop (1hr per week)
Workshop designed to consolidate and enrich students’ knowledge and understanding of Spanish grammar and syntax. All major areas of grammar will be encountered, laying the foundations for future study of the language and its nuances.
3. Specialised Language Cursillo (1hr per week)
Cursillo offers language skills for special purposes providing career development, linguistic and socio-cultural knowledge important to work-related situations in different fields.
4. Conversation Class (1hr per week)
Conversation class is led by a native speaker of Spanish and compliments the content of the Language Hour. Students will meet in small groups to discuss, debate, and present on the main themes of the course.
On successful completion of the modules students should:
1. be able to read Spanish texts in a variety of forms and demonstrate a sensitivity to their detail and nuance in speech, writing, and when translating;
2. be able to produce Spanish texts appropriate to different requirements and registers;
3. be able to investigate, structure, and present a complex argument in longer pieces of written work;
4. be able to communicate using more sophisticated grammatical and syntactical constructions with a good level of accuracy (without basic errors).
On successful completion of the modules students should have developed the following range of skills: comprehensive dexterity using Spanish grammar; translation skills; text analysis; essay writing; lexicographical skills; report writing skills; IT skills; presentation skills; spoken language skills.
Coursework
35%
Examination
40%
Practical
25%
40
SPA1101
Full Year
24 weeks
Vectors: Vectors in the plane and space. Coordinates, scalar product, projections, and curl product.
Complex numbers: Concept of complex plane, vectorial and exponential representation of complex numbers. Fundamental operations with complex numbers: sum, subtraction, product, division, power and roots, and complex conjugate, Euler and de Moivre’s theorems
Fundaments of trigonometry: Sine, cosine, tangent functions. Their graphs in one dimensions, their representation on the unitary sphere, and representation as complex exponentials.
Elements of linear algebra: Definition of matrices and operations. Determinant of a matrix. Solution of a system of linear equations. Gauss’ elimination method. Eigenvalues/eigenvectors. Definition and basic properties of a vectorial space, isomorphisms and homomorphisms. Generalised definition of norm and scalar product.
Elements of Euclidean geometry: equation of a line and a plane. Equation of the circle and the ellipse.
Analysis of a single-variable function: Definition of a function. Definition of limit and derivative. Methods to calculate limits and derivatives. Definition of continuity and singularities. Study of a function.
Taylor and MacLaurin series and approximation of single-variable function: definition of orders of expansion
Integration in one variable: definition of definite and indefinite integral, integration by parts and by substitution, integral of a rational function, Gaussian integrals.
Ordinary differential equations: Definition of linearity and order of differential equations. Solutions for linear differential equations and main properties. Solution of specific non-linear cases.
Probability distributions: Probability concepts. Binomial, poisson and normal distributions.
Elements of discrete calculus: Series with their limit and convergence theorems and methods.
Display knowledge of, and apply practically, a range of mathematical techniques and properties in the areas of trigonometry, Euclidean geometry, probability, vectors, linear algebra, complex numbers, and single and multi-variable calculus.
Formulate mathematical problems and obtain analytical or approximate solutions.
Problem solving. Communicating mathematical concepts in a clear and concise manner both orally and in written form. Working independently and meeting deadlines.
Coursework
0%
Examination
70%
Practical
30%
40
PHY1002
Full Year
24 weeks
Periodicity and symmetry, basic crystallographic definitions, packing of atomic planes, crystal structures, the reciprocal lattice, diffraction from crystals, Bragg condition and Ewald sphere.
Lattice waves and dispersion relations, phonons, Brillouin zones, heat capacity, density of vibrational states, Einstein and Debye models of heat capacity, thermal conductivity, thermal expansion and anharmonicity.
Concepts related to phase transitions in materials such as: free energy, enthalpy, entropy, order parameter, classification of phase transitions, Landau theory.
Electronic band structure, including: failures of classical model for metals and semiconductors, free electron gas description of metals, density of states, Fermi Dirac statistics, electronic heat capacity, development of band structure, prediction of intrinsic semiconducting behaviour, doping
Students will be able to:
Recognise and define the fundamental concepts used to describe properties of the solid state such as simple crystal structures and symmetries, diffraction and the reciprocal lattice, vibrational and thermal properties, phase changes, and electrical properties, and to demonstrate conceptual understanding of these concepts.
Show how relevant theoretical models can be developed to establish properties of materials and explain how these have been exploited in technological devices.
Plan, execute and report the results of an experiment or investigation, and compare results critically with predictions from theory
Problem solving. Searching for and evaluating information from a range of sources. Written communication of scientific concepts in a clear and concise manner. Working independently and meeting deadlines.
Coursework
40%
Examination
60%
Practical
0%
20
PHY2002
Spring
12 weeks
Advanced linear algebra: Definition and basic properties of a generic vectorial space, isomorphisms and homomorphisms. Generalised definition of scalar product and norm, base of a vectorial space, orthonormality.
Fourier series and Fourier transform. The Dirac delta function, Parseval’s theorem and the convolution theorem.
Partial differential equations: method of characteristics, PDE classification, d’Alembert’s solution, separation of variables.
Hamiltonian Mechanics. Definition of generalized and conjugated variables, principle of minimum action, Lagrangian and Hamiltonian formalism, Poisson’s brackets.
Students will be able to:
Display knowledge of, and apply practically, a range of mathematical techniques and properties in advanced mathematical techniques and concepts including linear algenbra, Fourier series and transforms, partial differential equations,and Lagrangian and Hamiltonian mechanics.
Formulate mathematical problems of physical systems and obtain analytical or approximate solutions.
Problem solving. Communicating mathematical concepts in a clear and concise manner both orally and in written form. Working independently and with a group of peers. Time management and the ability to meet deadlines.
Coursework
40%
Examination
60%
Practical
0%
20
PHY2006
Autumn
12 weeks
Electrostatics and magnetostatics.
Coulomb, Gauss, Faraday, Ampère, Lenz and Lorentz laws
Wave solution of the Maxwell’s equations in vacuum and the Poynting vector.
Polarisation of E.M. waves and behaviour at plane interfaces.
Propagation of light in media (isotropic dielectrics). Faraday and Kerr effects.
Temporal and spatial coherence of light. Interference and diffraction
Geometrical optics and matrix description of optic elements
Optical cavities and laser action.
Students will be able to:
Define and describe the fundamental laws of electricity and magnetism, understand their physical significance, and apply them to well-defined physical problems.
Formulate and manipulate Maxwell’s equations to obtain electromagnetic wave equations, solving them for propagation in vacuum, isotropic media, and at interfaces.
Explain and formulate examples of optical phenomena such as interference, diffraction, Faraday and Kerr effects, laser action, and manipulation of light by optical components.
Plan, execute and report the results of an experiment or investigation, and compare results critically with predictions from theory
Problem solving. Searching for and evaluating information from a range of sources. Written communication of scientific concepts in a clear and concise manner. Working independently and meeting deadlines.
Coursework
40%
Examination
60%
Practical
0%
20
PHY2004
Spring
12 weeks
Quantum history, particle waves, uncertainty principle, quantum wells, Schrödinger wave equation SWE.
1D SWE Solutions:
Infinite and finite square potential well, harmonic potential well, particle wave at a potential step, particle wave at a potential barrier, quantum tunnelling, 1st order perturbation theory.
3D Solutions of SWE:
Particle in a box, hydrogen atom, degeneracy.
Statistical Mechanics:
Pauli exclusion principle, fermions, bosons, statistical distributions, statistical entropy, partition function, density of states. Examples of Boltzmann, Fermi-Dirac, Bose-Einstein distributions.
Demonstrate how fundamental principles in quantum and statistical mechanics are derived and physically interpreted. In particular the uncertainty principle, the Schrödinger wave equation, tunnelling, quantum numbers, degeneracy, Pauli exclusion principle, statistical entropy, Boltzmann, Fermi-Dirac and Bose-Einstein distributions.
Obtain and interpret solutions of the Schrödinger wave equation in 1D for several simple quantum wells and barriers, and in 3D for a particle in a box and the hydrogen atom.
Apply quantum mechanics and statistical distributions to explain different physical phenomena and practical applications.
Plan, execute and report the results of an experiment or investigation, and compare results critically with predictions from theory
Problem solving. Searching for and evaluating information from a range of sources. Written communication of scientific concepts in a clear and concise manner. Working independently and meeting deadlines.
Coursework
40%
Examination
60%
Practical
0%
20
PHY2001
Autumn
12 weeks
Building on skills acquired at Level 1, this module aims to develop more advanced language skills in spoken and written language. Students will be required to take on increasingly complex tasks which require them to be aware of and use different written and spoken styles and registers. Task will promote linguistic, sociolinguistic and cultural awareness at a more advanced level. The module will contain the following elements:
1. Text-based class – (1 hour a week).
This class will focus on developing skills in reading, writing, literary and non literary translation. Students will be required to read and respond to texts which deal with current issues in Spanish speaking countries in Europe and Latin America.
2. Translation into English Workshop ( 1 hr per week)
Students will develop their ability to respond to a range of source text types of an appropriate level of difficulty, grouped according to the course themes. They will also develop editing skills and improve their expression in English. Study of Spanish grammar in context will be embedded into the class.
3. Oral class ( 1 hr per week)
This class will encourage students to develop their skills in spoken language with an emphasis on being able to communicate information and a point of view and on eliminating basic errors from spoken language as well as developing fluency in spoken Spanish
4. Cursillo ( 1 hr per week)
This class will focus on preparing students for the year abroad and on highlighting and developing the professional skills which students develop as a result of studying Spanish at degree level
There will be an extra hour of language tuition for ex-beginners
On successful completion of the modules students should:
1. be able to demonstrate a level of fluency, accuracy and spontaneity in speech and writing, and a wide range of vocabulary and expression, so as to be able to discuss a range of complex issues.
2. be able to read a wide variety of Spanish texts (fiction and non fiction) and identify important information and ideas within them.
3. be able to demonstrate a good grasp of structures of the language covered in the module and identify and use appropriate reference works including dictionaries and grammars.
4. be able to organise and present a coherent argument in Spanish relating to topics covered in the course, and present their knowledge and ideas in a range of formats and registers
On successful completion of the modules students should have developed the following range of skills: Translation skills; text analysis; essay writing; lexicographical skills; report writing skills; IT skills; presentation skills; spoken language skills - including practical language knowledge for living and working abroad
Coursework
35%
Examination
40%
Practical
25%
40
SPA2101
Full Year
24 weeks
Introduction to placement for Physics students, CV building, international options, interview skills, assessment centres, placement approval, health & safety and wellbeing. Workshops on CV building and interview skills. This module is delivered in-house with the support of the QUB Careers Service and external experts.
To identify gaps in personal employability skills. To plan a programme of work to result in a successful work placement application.
Plan self-learning and improve performance, as the foundation for lifelong learning/CPD. Decide on action plans and implement them effectively. Clearly identify criteria for success and evaluate their own performance against them .
Coursework
100%
Examination
0%
Practical
0%
0
PHY2010
Autumn
12 weeks
Students complete a work, volunteer or study placement in fulfilment of the residence abroad requirements associated with their chosen Physics degree.
On successful completion of this module students should be able to demonstrate:
- Advanced linguistic skills (where appropriate)
- Enhanced cultural and intercultural awareness
- An understanding of the work environment and professional skills OR an understanding of a different university system and enhanced academic skills
Students undertaking the placement will develop their skills in the following areas: linguistic skills (reading, writing, listening, speaking); professional or academic skills; cultural and intercultural awareness; personal development.
Coursework
0%
Examination
0%
Practical
100%
120
PHY3999
Full Year
30 weeks
Development of oral presentation skills. Presentations to large groups/peers in a research or popular science context. Probing scientific understanding, critiquing presentations, peer review. Entrepreneurship, career guidance, CV writing, interview techniques. Essay writing and scientific writing skills
Students will be able to:
Search for, evaluate and reference relevant information from a range of sources
Communicate general scientific topics in a clear and concise manner both orally and in a written format with proper regard for the needs of the audience.
Critically question and evaluate the work of peers
Critically self-reflect on progression of skills, academic performance, entrepreneurship and future prospects
Problem solving. Scientific writing. Entrepreneurship. Working independently and with a group of peers. Time management and the ability to meet deadlines.
Coursework
30%
Examination
0%
Practical
70%
20
PHY3008
Both
12 weeks
Building on skills acquired at level 2, and during residence abroad, this module aims to develop advanced competence in the target language. Linguistic, sociolinguistic and cultural awareness will be consolidated and deepened. The module will contain the following elements:
1. Text- based work in the target language (1 hour per week)
This contact hour is centred upon skills in persuasive and report writing, drawing upon a variety of contemporary source texts in Spanish, which are grouped thematically. A range of language acquisition and development methods will be employed: group discussion, reading and critical analysis, summary & paraphrase and responsive writing.
2. Translation into English (1 hour per week)
Students will build upon translation skills embedded at Levels 1 and 2 to deepen their ability to respond to a range of source text types of an advanced level of difficulty, grouped according to the course themes as for Hour 1. They will also develop editing skills and improve their expression in English.
3. Contextual study (1 hour per week)
The research led strand will introduce students to literary, cultural and historical source material from Spain and Latin America, deepening and contextualising the linguistic elements of the module by placing them in a broader socio-historical context.
4. Conversation class (1 hour per week)
Conversation class is led by a native speaker of Spanish and complements the content of the Language Hour. Students will meet in small groups to discuss, debate, and present on the main themes of the course
On Successful completion of the Module Students should:
1) Be able to demonstrate a high level of fluency, accuracy and spontaneity in their written and spoken Spanish, including the use of a broad variety of linguistic structures and vocabulary, congruent with carrying out activities in Spanish in a professional environment
2) Be able to deal with a broad variety of material in the target language, including material which is complex and abstract, and which involves a variety of genres, dialects and registers;
3) Be able to synthesise knowledge, identify key points, and structure and present arguments at a high level in a range of formats and registers
On successful completion of the modules students should have developed the following range of skills: Advanced skills in translation and textual analysis; the ability to argue at length and in detail about a topic in both Spanish & English, lexicographical skills; report writing skills; IT skills; presentation skills; spoken language skills
Coursework
35%
Examination
40%
Practical
25%
40
SPA3101
Full Year
24 weeks
Computing coding skills and optimization techniques.
Solution of ordinary differential equations with, for example, Runge Kutta 4th order method.
Students to choose from a range of computational projects including projects to solve ordinary differential equations, for example in solution of the 1D time independent Schrödinger Equation with the Shooting method, and partial differential equations, for example simulation of a wave on a string.
Data analysis techniques, for example, coping with noise and experimental uncertainty.
Students will be able to:
Analyse physical systems and write computer programs to model them.
Use computational methods for robust analysis of experimental data.
Problem solving with computing methods and computer programming. Searching for and evaluating information from a range of sources. Communicating scientific concepts in a clear and concise manner both orally and in written form. Working independently and with a group of peers. Time management and the ability to meet deadlines.
Coursework
100%
Examination
0%
Practical
0%
20
PHY3009
Autumn
12 weeks
Nuclear reaction classifications, scattering kinetics, cross sections, quantum mechanical scattering, Scattering experiments and the nuclear shell model, the inter-nucleon force, partial waves. Fermi theory of beta decay. Nuclear astrophysics and nuclear fission power generation. Elementary particles; symmetry principles, unitary symmetry and quark model, particle interactions.
Students will be able to:
Show how theoretical concepts can be used to develop models of the nuclear structure, nuclear reactions, particle scattering, and beta decay, and report on supporting experimental evidence.
Describe the principles of and evidence for the Standard Model
Apply theoretical models to make quantitative estimates and predictions in nuclear and particle physics.
Problem solving. Searching for and evaluating information from a range of sources. Written communication of scientific concepts in a clear and concise manner. Working independently and meeting deadlines.
Coursework
20%
Examination
80%
Practical
0%
20
PHY3005
Spring
12 weeks
Dielectrics, including: concepts of polarization, polarisability, Mossotti field, contributions to polarization, the Mossotti catastrophe, ferroelectricity, soft mode descriptions of ferroelectricity and antiferroelectricity, Landau-Ginzburg-Devonshire theory, displacive versus order-disorder ferroelectrics.
Magnetism, including: underlying origin of magnetism, the link between dipole moment and angular momentum, diamagnetism, paramagnetism (classical and quantum treatments), ferromagnetism and the Weiss molecular field, antiferromagnetism.
Electronic transport in metals, including: Lorentz-Drude classical theories and the Sommerfeld quantum free electron model. Influence of band structure on electron dynamics and transport. Electron scattering.
Magnetotransport, including cyclotron resonance, magnetoresistance and Hall effect
Students will be able to:
Explain how lattice periodicity, structure and both classical and quantum mechanics lead to general concepts and observed properties of metals, dielectrics and magnetic materials.
Formulate specific theoretical models of the properties of metals, dielectrics and magnetic materials and use these to make quantitative predictions of material properties.
Problem solving. Searching for and evaluating information from a range of sources. Written communication of scientific concepts in a clear and concise manner. Working independently and meeting deadlines.
Coursework
20%
Examination
80%
Practical
0%
20
PHY3002
Spring
12 weeks
Relativity:
Einstein's postulates. The Lorentz transformation and consequences. 4-vector formulation. Relativistic particle dynamics. Relativistic wave dynamics. Relativistic electrodynamics.
Quantum Mechanics:
The Lagrangian and Hamiltonian formalism. Wavefunctions and operators. The Schrödinger equation. The harmonic oscillator. Three-dimensional systems: angular momentum. Three-dimensional system: spherical harmonics. Composition of angular momenta and spin. The Hydrogen atom. Special distributions: Bose-Einstein and Fermi-Dirac statistics. Bell inequality and quantum entanglement. Perturbation theory: time-independent perturbations. Perturbation theory: periodic perturbations
Students will be able to:
State the fundamental postulates of relativity and quantum mechanics, develop the mathematical formalism of these subjects.
Solve specific physical problems using the formalism of relativity and quantum mechanics.
Problem solving. Searching for and evaluating information from a range of sources. Written communication of scientific concepts in a clear and concise manner. Working independently and meeting deadlines.
Coursework
20%
Examination
80%
Practical
0%
20
PHY3001
Autumn
12 weeks
Advanced stellar structure and evolution: physics of stellar interiors; concepts of single-star evolution; end points of stellar evolution
Radiative transfer: radiative transfer in solar and stellar atmospheres; statistical and ionization equilibrium, plasma diagnostics and line broadening processes
Galaxies: the Milky Way galaxy; galaxy properties; physics of the interstellar medium, theories of galaxy formation and evolution
Students will be able to:
Demonstrate a detailed comprehension of the main concepts underpinning modern astrophysics with emphasis on stellar interiors/atmospheres, stellar evolution and galaxy structure / evolution.
Explain the physics of stars and stellar evolution, and be able to describe the physical state of stars at all stages of their lives, and critically compare their fates and the various classes of objects they leave behind.
Understand and be able to link the physical conditions existing in a variety of astrophysics environments, including stellar interiors, stellar atmospheres and galaxies to observations (including spectroscopy) and the principles of radiative transfer.
Describe the properties of galaxies, their constituents and their evolution.
Apply their knowledge to unfamiliar astrophysical problems.
Problem solving. Searching for and evaluating information from a range of sources. Written communication of scientific concepts in a clear and concise manner. Working independently and meeting deadlines.
Coursework
20%
Examination
80%
Practical
0%
20
PHY3003
Spring
12 weeks
Fundamental principles, and technical and clinical applications of: interaction of electromagnetic radiation and ionising radiation with the body, lasers for therapy and imaging, ultrasound, radiation imaging techniques, radiotherapy, magnetic resonance imaging.
Students will be able to:
Describe, apply and discuss the underlying physical principles of techniques used for medical imaging techniques and treatment of diseased tissue with light and radiation.
Evaluate the relative merits of current and future imaging and therapeutic techniques.
Make quantitative estimates of relevant physical parameters such as penetration depth and radiation dose.
Problem solving. Searching for and evaluating information from a range of sources. Communicating scientific concepts in a clear and concise manner both orally and in written form. Working independently and with a group of peers. Time management and the ability to meet deadlines.
Coursework
50%
Examination
50%
Practical
0%
20
PHY3006
Autumn
12 weeks
Maxwell's equations, propagation of EM waves in dielectrics, conductors, anisotropic media, optical fibres/waveguides, non-linear optics. Polarisation, reflection and transmission at boundaries, Fresnel's equations. Thin/thick optical lenses, matrix methods, aberrations and diffraction.
Students will be able to:
Demonstrate knowledge and conceptual understanding of Maxwell's equations and their application to the propagation of electromagnetic waves in various media and their manipulation using optical components.
Solve problems using mathematical techniques such as matrix methods and vector calculus to model electric/magnetic fields, the propagation of light, and to obtain analytical or approximate solutions.
Problem solving. Searching for and evaluating information from a range of sources. Written communication of scientific concepts in a clear and concise manner. Working independently and meeting deadlines.
Coursework
20%
Examination
80%
Practical
0%
20
PHY3004
Autumn
12 weeks
Students will undertake a single research project within a Research Centre in the School or at an appropriate external organisation. Safety, risk assessment, and ethics training. Searching and evaluating scientific literature. Students will work full-time to complete all laboratory/computational results by the end of the first semester.
Students will be able to:
Plan, execute and report the results of an experiment or investigation, and compare critically with previous experiments or theory.
Exploit computer technology to analyse and present data
Demonstrate knowledge and understanding in a selected research topic in Physics, the current trends in this field, and developments at the frontiers of this subject
Generate research results or technical innovations which could be included in a scientific publication
Appreciate the importance of health and safety and scientific ethics, and perform a project risk assessment
Searching for and evaluating information from a range of sources. Communicating scientific concepts in a clear and concise manner both orally and in written form. Working independently and within a research group. Time management and the ability to meet deadlines.
Coursework
85%
Examination
0%
Practical
15%
60
PHY4001
Autumn
12 weeks
Introduction to Plasmas: applications, fundamental concepts
Single particle orbit theory: Motion of charged particles in constant/varying electric and magnetic fields, particle drift
Plasma as Fluid: Two fluids model, Plasma oscillations and frequency.
Waves in Plasma: Electron plasma wave, Ion acoustic wave, electromagnetic wave propagation in plasma
Collisions and Resistivity: Concept of plasma resistivity, Collisional absorption of laser in plasma
Intense laser plasma Interaction: Resonance absorption, Landau damping, Ponderomotive force, Interaction in the relativistic regime, particle (electron and ion) acceleration mechanisms
Students will be able to:
Demonstrate knowledge and understanding of the physics of plasmas relevant to a range of research areas from astrophysics to laser-plasma interactions.
Understanding and derive the behaviour of charges particles in presence of electric and magnetic fields.
Derive and interpret various plasma phenomenon using fluid theory
Review scientific literature and report on current research topics individually or as part of a group.
Problem solving. Searching for and evaluating information from a range of sources. Written and oral communication of scientific concepts in a clear and concise manner. Working independently or as part of a group and meeting deadlines.
Coursework
30%
Examination
70%
Practical
0%
10
PHY4008
Spring
6 weeks
Interactions of radiation with matter; Introduction to radio-biology; Interaction of Charged Particles with Biological Matter; Modern approaches to Radiotherapy; Selected Modern Radiation Research Topics
Students will be able to:
Comprehend the basis for radiation-based physical measurements pertinent to the human body
Appreciate the role of modern radiation medical devices and the underlying physics at work
Analyse and quantify the physical processes at work in a range of medical applications.
Problem solving. Searching for and evaluating information from a range of sources. Written and oral communication of scientific concepts in a clear and concise manner. Working independently and meeting deadlines.
Coursework
70%
Examination
0%
Practical
30%
10
PHY4003
Spring
6 weeks
Basic laser physics: Population inversion and laser materials, gain in a laser system, saturation, transform limit, diffraction limit
Short pulse oscillators: Cavities, Q-switching, cavity modes, mode locking
Amplification: Beam transport considerations (B-Integral), chirped pulse amplification, stretcher and compressor design, white light generation, optical parametric chirped pulse amplification.
Different types of lasers: Fiber lasers, laser diodes, Dye lasers, high performance national and international laser facilities
Applications of state of the art lasers: Intense laser-matter interactions, high harmonic generation : perturbed atoms to relativistic plasmas, generation of shortest pulses of electromagnetic radiation
Students will be able to:
Demonstrate knowledge and understanding of the basics of modern laser systems, and how the unique properties of the high power lasers and recent technological advances are opening up new research fields including next generation particle and light sources.
Correlate the fundamental parameters of specific lasers or laser facilities to potential applications or research projects.
Review published material on topics of high intensity laser-plasma interactions
Problem solving. Searching for and evaluating information from a range of sources. Written and oral communication of scientific concepts in a clear and concise manner. Working independently or as part of a group and meeting deadlines.
Coursework
30%
Examination
70%
Practical
0%
10
PHY4007
Spring
6 weeks
Observational overview
Accreting neutron stars and pulsars
Pulsar emission mechanisms
Black holes, active galactic nuclei, explosive transients (gamma-ray bursts, supernovae), and supernova remnants
Role of jets
Non-electromagnetic processes; cosmic rays, gravitational waves
Particle acceleration
Radiation processes (e.g., Bremsstrahlung, inverse Compton, etc.)
Stellar dynamos
Flux emergence
Magnetic topologies
Zeeman + Hanle effects
Magnetic reconnection and flares
Students will be able to:
Apply their knowledge of mathematics and physics from Levels 1-3 in an astrophysical context.
Understand the evolutionary history of binary systems containing compact degenerate objects;
Understand how high energy processes such as accretion and angular momentum transfer come into play in a variety of astrophysical objects on vastly different scales.
Develop a sense of relevant observational signatures of high energy astrophysical processes that may be both electromagnetic and non-electromagnetic in nature.
Critically compare the evidence from observations with the predictions from theory
Problem solving. Searching for and evaluating information from a range of sources. Written and oral communication of scientific concepts in a clear and concise manner. Working independently and meeting deadlines.
Coursework
30%
Examination
70%
Practical
0%
10
PHY4006
Spring
6 weeks
Fundamental physics underlying electron microscopy-based analysis to investigate the delicate link between crystal structure and chemical composition at the nanoscale, and its impact on properties, with special focus on functional oxides and semiconductors. Physical principles of spectroscopy, Infrared and Raman spectroscopy/microscopy, Scanning nonlinear optical microscopy and scanning probe microscopy with specific applications towards study of phase transitions, domains and ferroic materials.
Students will be able to:
Demonstrate knowledge and understanding of physical principles underpinning different spectroscopy and microscopy techniques relevant to study of phase transitions, ferroic materials and semiconductors.
Identify, design and propose microscopy based experimental setups to study physical phenomena in solid state.
Review and discuss scientific literature, and report on current research topics individually or as part of a group.
Problem solving. Searching for and evaluating information from a range of sources. Written and oral communication of scientific concepts in a clear and concise manner. Working independently or as part of a group and meeting deadlines.
Coursework
30%
Examination
70%
Practical
0%
10
PHY4009
Spring
6 weeks
Overview of Solar system structure. Properties of asteroids, comets, Trans-Neptunian Objects. Solar System evolution. Planetary System formation including molecular clouds, Jean’s mass, disc formation, angular momentum considerations. Protoplanetary disks – observed and theoretical structure and lifetimes, planet formation. Finding exoplanets. Exoplanet properties. Planet migration. Planetary interiors. Exoplanet theory and observation. Habitability.
Students will be able to:
Understand the structure of planetary systems and protoplanetary disks, and describe how they are formed through the comparison of observations and theory.
Understand different techniques for exoplanet discovery and calculate the values of planetary system parameters required for this.
Use knowledge of physics to constrain the orbital evolution of planets and their interior structure.
Describe the observed properties of planetary atmospheres by combining measurements with theory, and explain how these properties allow possible habitats for life to be evaluated.
Problem solving. Searching for and evaluating information from a range of sources. Written and oral communication of scientific concepts in a clear and concise manner. Working independently and meeting deadlines.
Coursework
100%
Examination
0%
Practical
0%
10
PHY4005
Spring
6 weeks
Introduction to a basic Linux scientific computational environment. Introduction to Monte-Carlo radiation transport simulation. Proton and photon interactions with matter. Applications of radiation transport to simulate aspects of medical imaging and radiotherapy. Validation of simulations and assessment of errors.
Students will be able to:
Solve a range of problems computationally involving the transport of radiation through matter, including assessing the validity of and errors associated with such simulations.
Problem solving. Searching for and evaluating information from a range of sources. Written and oral communication of scientific concepts in a clear and concise manner. Working independently or as part of a group and meeting deadlines.
Coursework
100%
Examination
0%
Practical
0%
10
PHY4004
Spring
6 weeks
Physics of nanomaterials with the emphasis on fabrication of materials and applications in magnetic recording and photonics. Magnetic recording materials including bit patterned media and spin valves. Nanostructures for surface plasmon detection. Optical properties of metal nanoparticles and nanostructures. Concept of metamaterials and negative refractive index materials. Examples of applications of nanophotonic devices e.g. in imaging, sensing and data storage.
Students will be able to:
Demonstrate knowledge and understanding of physical principles underpinning nanostructured materials and of nano-optics and its applications.
Identify design and propose fabrication routes to create nanostructured materials for various applications.
Review and discuss scientific literature, and report on current research topics individually or as part of a group.
Problem solving. Searching for and evaluating information from a range of sources. Written and oral communication of scientific concepts in a clear and concise manner. Working independently or as part of a group and meeting deadlines.
Coursework
30%
Examination
70%
Practical
0%
10
PHY4010
Spring
6 weeks
Observational overview
Distance scale and redshift
Friedmann equation and expansion, and Universal geometry
Cosmological models
Observational parameters
The cosmological constant
Age of the universe
Density of the universe and dark matter
Cosmic microwave background
Early universe
Nucleosynthesis – the origin of light elements
Inflationary universe and the Initial singularity
Students will be able to:
Apply their knowledge of basic physics including thermodynamics, atomic physics and nuclear physics to understand the principles of modern cosmology.
Appreciate the concepts of the expanding Universe, redshift, isotropy and the mass energy content of the Universe.
Formulate and manipulate equations of Newtonian gravity to derive the Friedmann equation. Solve this equation to obtain simple cosmological models.
Explain the origin of the cosmic microwave background and the nucleosynthesis of the light elements in the big bang theory.
Understand how precision measurements constrain the Hubble parameter, the age and the matter and energy density of the Universe. Understand the observational evidence for dark matter and the accelerating expansion.
Critically compare the evidence from observations with the predictions from theory
Problem solving. Searching for and evaluating information from a range of sources. Written and oral communication of scientific concepts in a clear and concise manner. Working independently and meeting deadlines.
Coursework
50%
Examination
0%
Practical
50%
10
PHY4016
Spring
6 weeks
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Entry requirements
AAA including Mathematics, Physics and Spanish
OR
A*AB including Mathematics, Physics and Spanish
H2H2H3H3H3H3 including Higher Level grade H2 in Mathematics, H2 in Physics and H3 in Spanish
36 points overall including 6 6 6 at Higher Level including Mathematics, Physics and Spanish.
A minimum of a 2:2 Honours Degree, provided any subject requirement is also met.
All applicants must have GCSE English Language grade C/4 or an equivalent qualification acceptable to the University.
In addition, to the entrance requirements above, it is essential that you read our guidance below on 'How we choose our students' prior to submitting your UCAS application.
Applications are dealt with centrally by the Admissions and Access Service rather than by the School of Mathematics and Physics. Once your on-line form has been processed by UCAS and forwarded to Queen's, an acknowledgement is normally sent within two weeks of its receipt at the University.
Selection is on the basis of the information provided on your UCAS form. Decisions are made on an ongoing basis and will be notified to you via UCAS.
For entry last year, applicants for programmes in the School of Mathematics and Physics must have had, or been able to achieve, a minimum of five GCSE passes at grade C/4 or better (to include English Language and Mathematics), though this profile may change from year to year depending on the demand for places. The Selector also checks that any specific entry requirements in terms of GCSE and/or A-level subjects can be fulfilled.
Offers are normally made on the basis of three A-levels. The offer for repeat applicants may be one grade higher than for first time applicants. Grades may be held from the previous year.
For applicants offering the Irish Leaving Certificate, please note that performance at Irish Junior Certificate (IJC) is taken into account. For last year’s entry, applicants for this degree must have had a minimum of five IJC grades at C/Merit. The Selector also checks that any specific entry requirements in terms of Leaving Certificate subjects can be satisfied.
Applicants offering other qualifications will also be considered. The same GCSE (or equivalent) profile is usually expected of those applicants offering other qualifications.
The information provided in the personal statement section and the academic reference together with predicted grades are noted but, in the case of degree courses in the School of Mathematics and Physics, these are not the final deciding factors in whether or not a conditional offer can be made. However, they may be reconsidered in a tie break situation in August.
A-level General Studies and A-level Critical Thinking would not normally be considered as part of a three A-level offer and, although they may be excluded where an applicant is taking four A-level subjects, the grade achieved could be taken into account if necessary in August/September.
Applicants are not normally asked to attend for interview.
If you are made an offer then you may be invited to a Faculty/School Visit Day, which is usually held in the second semester. This will allow you the opportunity to visit the University and to find out more about the degree programme of your choice and the facilities on offer. It also gives you a flavour of the academic and social life at Queen's.
If you cannot find the information you need here, please contact the University Admissions and Access Service (admissions@qub.ac.uk), giving full details of your qualifications and educational background.
Our country/region pages include information on entry requirements, tuition fees, scholarships, student profiles, upcoming events and contacts for your country/region. Use the dropdown list below for specific information for your country/region.
If you need to improve your English language skills before you enter this degree programme, INTO Queen's University Belfast offers a range of English language courses. These intensive and flexible courses are designed to improve your English ability for admission to this degree.
INTO Queen's offers a range of academic and English language programmes to help prepare international students for undergraduate study at Queen's University. You will learn from experienced teachers in a dedicated international study centre on campus, and will have full access to the University's world-class facilities.
These programmes are designed for international students who do not meet the required academic and English language requirements for direct entry.
According to the Institute for Fiscal Studies, 5 years after graduation, Physics graduates earn 15 per cent more on average than other graduates (IFS 2018) with female graduates the 4th highest earners compared to all other subjects (5th for males).
Physics-related jobs are available in research, development, and general production in many high technology and related industries. These include medicine, biotechnology, electronics, optics, aerospace, computation and nuclear technology. Physics graduates are also sought after for many other jobs, such as business consultancy, finance, business, insurance, taxation and accountancy, where their problem-solving skills and numeracy are highly valued. In Northern Ireland alone in 2019, there were almost 49,000 jobs in physics based industries which had a £10bn turnover (Institute of Physics Report 2019).
About half of our students go on to further study after graduation. Some physics graduates take up careers in education, while a number are accepted for a PhD programme in Physics, which can enhance employment prospects or provide a path to a research physicist position. Most of the rest of our graduates move rapidly into full-time employment, most in careers that require a degree.
As part of the assessment within our modules, students will have to prepare reports, give presentations and work together within small groups. Students will become experienced in using spreadsheet and word processing software to analyse and communicate their findings. Additionally, basic computer programming is taught to allow computational modelling of physical phenomena, which can then be applied to many non-scientific areas of commerce and industry. The problem-solving and communication skills that are essential to scientific study are also recognised as important attributes for many other careers.
Typical career destinations of graduates include:
• Industrial Physics
• Telecommunications
• Medical Physics
• Research scientist
• Computer technology
• Forensic accountant
• Nuclear Physics
• Biophysics
• Education
• Financial analysis
Graduate employers include: BT; Seagate; Allstate; Andor; Civil Service; Randox; AquaQ; First Derivatives; NHS.
Students undertaking the Physics with Spanish degree will spend a year studying physics in a University in Spain.
Top performing students are eligible for a number of prizes within the School.
In addition to your degree programme, at Queen's you can have the opportunity to gain wider life, academic and employability skills. For example, placements, voluntary work, clubs, societies, sports and lots more. So not only do you graduate with a degree recognised from a world leading university, you'll have practical national and international experience plus a wider exposure to life overall. We call this Degree Plus/Future Ready Award. It's what makes studying at Queen's University Belfast special.
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Entry Requirements
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Fees and Funding
Northern Ireland (NI) 1 | £4,855 |
Republic of Ireland (ROI) 2 | £4,855 |
England, Scotland or Wales (GB) 1 | £9,535 |
EU Other 3 | £25,300 |
International | £25,300 |
1EU citizens in the EU Settlement Scheme, with settled status, will be charged the NI or GB tuition fee based on where they are ordinarily resident. Students who are ROI nationals resident in GB will be charged the GB fee.
2 EU students who are ROI nationals resident in ROI are eligible for NI tuition fees.
3 EU Other students (excludes Republic of Ireland nationals living in GB, NI or ROI) are charged tuition fees in line with international fees.
The tuition fees quoted above for NI and ROI are the 2024/25 fees and will be updated when the new fees are known. In addition, all tuition fees will be subject to an annual inflationary increase in each year of the course. Fees quoted relate to a single year of study unless explicitly stated otherwise.
Tuition fee rates are calculated based on a student’s tuition fee status and generally increase annually by inflation. How tuition fees are determined is set out in the Student Finance Framework.
Depending on the programme of study, there may be extra costs which are not covered by tuition fees, which students will need to consider when planning their studies.
Students can borrow books and access online learning resources from any Queen's library. If students wish to purchase recommended texts, rather than borrow them from the University Library, prices per text can range from £30 to £100. Students should also budget between £30 to £75 per year for photocopying, memory sticks and printing charges.
Students undertaking a period of work placement or study abroad, as either a compulsory or optional part of their programme, should be aware that they will have to fund additional travel and living costs.
If a programme includes a major project or dissertation, there may be costs associated with transport, accommodation and/or materials. The amount will depend on the project chosen. There may also be additional costs for printing and binding.
Students may wish to consider purchasing an electronic device; costs will vary depending on the specification of the model chosen.
There are also additional charges for graduation ceremonies, examination resits and library fines.
There are different tuition fee and student financial support arrangements for students from Northern Ireland, those from England, Scotland and Wales (Great Britain), and those from the rest of the European Union.
Information on funding options and financial assistance for undergraduate students is available at www.qub.ac.uk/Study/Undergraduate/Fees-and-scholarships/.
Each year, we offer a range of scholarships and prizes for new students. Information on scholarships available.
Information on scholarships for international students, is available at www.qub.ac.uk/Study/international-students/international-scholarships.
Application for admission to full-time undergraduate and sandwich courses at the University should normally be made through the Universities and Colleges Admissions Service (UCAS). Full information can be obtained from the UCAS website at: www.ucas.com/students.
UCAS will start processing applications for entry in autumn 2025 from early September 2024.
The advisory closing date for the receipt of applications for entry in 2025 is still to be confirmed by UCAS but is normally in late January (18:00). This is the 'equal consideration' deadline for this course.
Applications from UK and EU (Republic of Ireland) students after this date are, in practice, considered by Queen’s for entry to this course throughout the remainder of the application cycle (30 June 2025) subject to the availability of places. If you apply for 2025 entry after this deadline, you will automatically be entered into Clearing.
Applications from International and EU (Other) students are normally considered by Queen's for entry to this course until 30 June 2025. If you apply for 2025 entry after this deadline, you will automatically be entered into Clearing.
Applicants are encouraged to apply as early as is consistent with having made a careful and considered choice of institutions and courses.
The Institution code name for Queen's is QBELF and the institution code is Q75.
Further information on applying to study at Queen's is available at: www.qub.ac.uk/Study/Undergraduate/How-to-apply/
The terms and conditions that apply when you accept an offer of a place at the University on a taught programme of study. Queen's University Belfast Terms and Conditions.
Download Undergraduate Prospectus
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Fees and Funding