BSc Physics (with Education)

Full Time
Degree of Bachelor of Science

UCAS Course Code
A-Level typical
BBB (2019/0 entry) See All Requirements
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Physics at UEA is a multi-faceted discipline, covering themes as diverse as quantum physics, fluid mechanics, geophysics and chemical physics. Our courses bring together expertise from across the Faculty of Science to deliver exciting, diverse and cutting-edge teaching, backed by pioneering research.

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New Building for Science and Engineering - Due to open in July 2019. Take an animated tour of our new £31 million state-of-the-art teaching and learning building on the UEA campus.

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Hear from our students. Find out what it’s like to be a part of the School of Physics at UEA.

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Hear from our students. Find out what it’s like to be a part of the School of Physics at UEA.

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UEA scientists are measuring some of the fastest processes on the planet to determine the effect that light has on proteins in living organisms, and the resulting structural changes that activate genetic switches.

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In their words

Steven Phaup, PGCE Secondary Graduate

Develop the knowledge and practical skills essential to physics, while pursuing your interest in Education. Taught in conjunction with the School of Education, you’ll gain hands-on teaching experience with a guaranteed placement in a local secondary school.

You’ll also complete compulsory modules in education research, alongside physics modules that you can tailor to your own specific interests. This is the ideal course to prepare for a teaching career, as well as other careers associated with science and communication, such as science journalism, science events and society careers, and science presentation in museums.


Our three-year Physics with Education degree will arm you with the skills and knowledge crucial to the study of physics. As you progress through the course you’ll be able to tailor its content to your specific interests by selecting from our optional modules.

Our course provides you with a guaranteed placement in a local secondary school. And you’ll be able to choose modules from the School of Education to further your understanding of education.

Towards the end of your time with us you’ll gain all-important independent research experience, completing a project in education research as well as one in your chosen area of physics.

Course Structure

The flexibility of our programme encourages you to explore and pursue your own specialist interests within physics and education as the course progresses.

Year 1

First year modules will cover the major areas of physics while giving you a solid grounding in mathematics. We’ll also encourage you participate in extracurricular education and science communication activities, held across the Science Faculty.

Year 2

In year two you’ll complete our compulsory work placement module, ‘Education in Action’. You’ll also be able to choose from a number of advanced optional modules, covering a diverse range of physics and education subjects.

Year 3

In your final year you’ll complete our compulsory ‘Education Research’ module, through which you’ll undertake an independent project within education.

You will also apply your developing scientific interests to a substantial independent physics research project in your final year.

Teaching and Learning

Our teaching combines lectures, small group seminars, workshops and practical sessions, with some including an element of programming.

Some lectures and practical sessions will take a ‘flipped’ approach, for which you’ll be expected to read and carry out specific tasks, prior to attending.

Independent study

You will have plenty of opportunity for independent study throughout your degree programme, as you complete coursework and prepare for exams. However your two final year research projects will truly exemplify your independent work. You’ll complete one in education and another in an aspect of physics that interests you most.


We employ a range of assessment methods to best reflect each module and what we hope you will gain from it.

Assessments will usually feature a combination of practical reports, data handling, project work, dissertations, course tests and examinations.

After the course

Our degree will prepare you to undertake a PGCE qualification or to begin teacher training through other routes, such as School-centred initial teacher training (SCITT).

If you decide not to pursue a career in teaching, your degree will also open up careers associated with science and communication, such as science journalism, science events and society careers, and science presentation in museums.

You could also decide to remain in the world of academia, studying for a Masters degree of PhD.

Career destinations

Examples of careers that you could enter include:

  • Teaching
  • Science communication
  • Publishing
  • Journalism
  • Research Scientist
  • Management Training

Course related costs

In addition to the standard fees, you’ll be expected to cover the costs of travel to and from your work placement as part of the ‘Education in Action’ module. You will also need to pay for and complete a DBS check prior to commencing the course.

Please see Additional Course Fees for details of course-related costs.

Course Modules 2019/0

Students must study the following modules for 120 credits:

Name Code Credits


This module explores the physics behind the generation and reception of music. You will be provided with an introduction to the fundamental principles of astrophysics, and will use these to explore a variety of astrophysical phenomena. You'll be introduced to the topics of uncertainties, accuracy and ethical behaviour in physics. You'll learn about acoustics, sound measurement and analysis, including more widely applicable concepts such as the behaviour waves and analysis using Fourier series. You will also study aspects of astrophysics including the history of astrophysics, radiation, matter, gravitation, astrophysical measurements, spectroscopy, stars and some aspects of cosmology. You will learn to predict differences between idealised physics and real life situations. You'll also improve your skills in problem solving, written communication, information retrieval, poster design, information technology, numeracy and calculations, time management and organisation.




You will be introduced to important topics in physics, with particular, but not exclusive, relevance to chemical and molecular physics. You will cover areas including optics, electrostatics and magnetism and special relativity.




You will be introduced to the major areas of classical physical chemistry: chemical kinetics, chemical thermodynamics, and electrolyte solutions as well as spectroscopy. Chemical kinetics will consider the kinetic theory of gases and the rate of processes, in particular either in the gas phase or in solution. The appropriate theoretical basis for understanding rate measurements will be developed during the course, which will include considerations of the order of reaction, the Arrhenius equation and determination of rate constants. Thermodynamics deals with energy relationships in large assemblies, that is those systems which contain sufficient numbers of molecules for 'bulk' properties to be exhibited and which, are in a state of equilibrium. Properties discussed will include the heat content or enthalpy (H), heat capacity (Cp, Cv), internal energy (U), heat and work. The First Law of Thermodynamics will be introduced and its significance explained. It is very important that scientists have an understanding of the behaviour of ions in solution, which includes conductivity and ionic mobility. The interaction of radiation with matter is termed spectroscopy. Three main topics will be discussed: (i) ultraviolet/visible (UV / Vis) spectroscopy, in which electrons are moved from one orbital to another orbital; (ii) infrared (vibrational) spectroscopy, a technique which provides important information on the variety of bond types that a molecule can possess; (iii) nuclear magnetic resonance spectroscopy (NMR), which allows 'molecular skeletons' to be identified.




You will cover differentiation, integration, vectors, partial differentiation, ordinary differential equations, further integrals, power series expansions, complex numbers and statistical methods as part of this module. In addition to the theoretical background there is an emphasis on applied examples. Previous knowledge of calculus is assumed. This module is the first in a series of three maths modules for those across the Faculty of Science that provide a solid undergraduate mathematical training. The follow-on modules are Mathematics for Scientists B and C.




This module comprises two parts: "Probability" and "Mechanics" Probability is the study of the chance of events occurring. It has important applications to understanding the likelihood of multiple events happening together and therefore to rational decision-making. In the first part of this module, you will start by studying probability as a measurement of uncertainty, and looking at statistical experiments and Bayes' theorem. You will then consider both discrete and continuous probability distributions and the concept of expectation. Finally you will consider applications of probability, including Markov chains and reliability theory. Newtonian mechanics provides a basic description of how particles and rigid bodies move in response to applied forces. In the second part of the module you will study Newton's laws of motion and how they can be applied to particle dynamics, vibrations, motion in polar coordinates, and conservation laws.




Understanding of natural systems is underpinned by physical laws and processes. You will explore the energy, mechanics, and physical properties of Earth materials and their relevance to environmental science using examples from across the Earth's differing systems. The formation, subsequent evolution and current state of our planet are considered through its structure and behaviour - from the planetary interior to the dynamic surface and into the atmosphere. You will study Plate Tectonics to explain Earth's physiographic features - such as mountain belts and volcanoes - and how the processes of erosion and deposition modify them. The distribution of land masses is tied to global patterns of rock, ice and soil distribution and to atmospheric and ocean circulation. You will also explore geological time - the 4.6 billion year record of changing conditions on the planet - and how geological maps can be used to understand Earth history. This course provides you with an introduction to geological materials - rocks, minerals and sediments - and to geological resources and natural hazards.



Students must study the following modules for 120 credits:

Name Code Credits


You will learn about the fundamentals of teaching and learning by working with young people and their teachers within a school placement. This is an exciting and highly interactive module that will be centred in either a primary school or secondary school, to suit your interests. You will have the opportunity to develop a broad range of transferable skills, particularly useful for those considering initial teacher training in the future.




Exploring fundamental aspects of thermodynamics and condensed matter physics, you'll be introduced to ideas about the electronic structure based on the free-electron Sommerfeld and band theories, along with the concept of phonons and their contribution to the heat capacity of a solid. Also you'll consider the structure, bonding and properties of solids, in particular electronic conductivity and magnetism, as well as atomic structure and atomic spectroscopy, and Entropy in terms of a macroscopic Carnot cycle and the statistical approach. Two important distributions of particles will be treated; Bose-Einstein and Fermi-Dirac. Changes of state, 1st and 2nd order phase transitions and the Clausius-Clapeyron equation will be described.




This module serves as an introduction to fluid dynamics, vector calculus and Fourier analysis.




This module is the third in a series of three mathematical units for students across the Faculty of Science. It covers matrix algebra and numerical methods, partial differential equations and solid mechanics. There is a continuing emphasis on applied examples, and the use of numerical computing software (Matlab) is extended with a dedicated programming component. The module is taught by mathematicians with considerable expertise in the use of mathematics in the natural/environmental sciences and is largely designed to equip students with the tools necessary for advanced second and third level modules, particularly those in the physical sciences.




You'll cover the foundation and basics of quantum theory and symmetry, starting with features of the quantum world and including elements of quantum chemistry, group theory, computer-based methods for calculating molecular wavefunctions, quantum information, and the quantum nature of light. The subject matter paves the way for applications to a variety of chemical and physical systems - in particular, processes and properties involving the electronic structure of atoms and molecules.




This module explores physics as an empirical science through a series of laboratory experiments that probe key concepts and physical laws. Your laboratory sessions will be underpinned by associated teaching surrounding the studied phenomena, and will complement topics addressed in other modules in the physics course.



Students must study the following modules for 120 credits:

Name Code Credits


This module explores concepts in physics through a series of advanced laboratory experiments, working in teams. The experiments are underpinned by associated teaching in other modules of the Physics course.




On this module you will study a selection of advanced topics in classical physics that provide powerful tools in many applications as well as provide a deep theoretical background for further advanced studies in both classical and quantum physics. The topics include analytical mechanics, electromagnetic field theory and special relativity. Within this module you will also complete a computational assignment, developing necessary skills applicable for computations in many areas of physics










This individual research module is compulsory for all Natural Sciences students and is only available to Natural Sciences students. It comprises supervised research in at least one area of science. It may involve research partners across the Norwich Research Park. The project can involve collection of data in the laboratory or in the field, and/or development of a piece of equipment, and/or development of software or a theoretical/numerical model, and/or analysis of pre-existing data from a variety of sources. It must include independent scientific analysis. It will be assessed by a written report, a presentation, and a web log maintained throughout the project.



Students will select 0 - 20 credits from the following modules:

Name Code Credits


A practical introduction to electronics, this module is structured to consider analogue electronics and digital electronics in turn. Topics you'll cover include passive and active components, including op-amps, transistors, logic gates, flip-flops and registers. Circuits you'll study include amplifiers, oscillators, modulators, combinational and sequential logic and state machines. You'll spend much of your time doing practical work - underpinned by lectures - where you will build prototypes circuits, as well as designing and building Printed Circuit Boards (PCBs).




What lies beneath our feet? This module addresses this question by exploring how wavefields and potential fields are used in geophysics to image the subsurface on scales of metres to kilometres. You'll study the basic theory, data acquisition and interpretation methods of seismic, electrical, gravity and magnetic surveys. A wide range of applications are covered, including archaeological geophysics, energy resources and geohazards. Highly valued by employers, this module features guest lecturers from industry who explain the latest 'state-of-the-art' applications and give you unique insight into real world situations. In taking this module, you'll normally expected to have a good mathematical ability, notably in calculus and algebra.




What lies beneath our feet? This module addresses this question by exploring how wavefields and potential fields are used in geophysics to image the subsurface on scales of metres to kilometres. You'll study the basic theory, data acquisition and interpretation methods of seismic, electrical, gravity and magnetic surveys. A wide range of applications are covered, including archaeological geophysics, energy resources and geohazards. Highly valued by employers, this module features guest lecturers from industry who explain the latest 'state-of-the-art' applications and give you unique insight into real world situations. In taking this module, you'll normally be expected to have a good mathematical ability, notably in calculus and algebra. This module also includes a one-week field course, currently held in the Lake District during Easter break. The cost of attending the field course is heavily subsidised by the School but students enrolling must commit to paying a sum to cover their attendance.




Processes in the Earth's interior exert a profound influence on all aspects of the Earth's system, and have done so throughout geological time. On this module, you'll explore all aspects of those processes from the creation and destruction of tectonic plates to the structure of the Earth's interior and the distribution and dissipation of energy within it. This will include: the theory and mechanisms of plate tectonics, the generation of magma and volcanism; the mechanisms behind earthquakes. We will also discuss the geological record of this activity, its evolution and impacts on the Earth.




The weather affects everyone and influences decisions that are made on a daily basis around the world. From whether to hang your washing out on a sunny afternoon, to which route a commercial aircraft takes as it travels across the ocean, weather plays a vital role. With that in mind, what actually causes the weather we experience? In this module you'll learn the fundamentals of the science of meteorology. You'll concentrate on the physical process that allow moisture and radiation to transfer through the atmosphere and how they ultimately influence our weather. The module contains both descriptive and mathematical treatments of radiation balance, thermodynamics, dynamics, boundary layers, weather systems and the water cycle. The module is assessed through a combination of one piece of coursework and an exam, and is designed in a way that allows those with either mathematical or descriptive abilities to do well, although a reasonable mathematical competence is essential, including basic understanding of differentiation and integration.




This module gives you an understanding of the physical processes occurring in the basin-scale ocean environment. We will introduce and discuss large scale global ocean circulation, including gyres, boundary currents and the overturning circulation. Major themes include the interaction between ocean and atmosphere, and the forces which drive ocean circulation. You should be familiar with partial differentiation, integration, handling equations and using calculators. Shelf Sea Dynamics is a natural follow-on module and builds on some of the concepts introduced here. We strongly recommend that you also gain oceanographic fieldwork experience by taking the 20-credit biennial Marine Sciences field course.




This module builds on understanding in wind, tidal and hydroelectric power and introduces theories and principles relating to a variety of renewable energy technologies including solar energy, heat pumps and geothermal sources, fuel cells and the hydrogen economy, biomass energy and anaerobic digestion. You will consider how these various technologies can realistically contribute to the energy mix. You will study the various targets and legislative instruments that are used to control and encourage developments. Another key aspect of the module is the study and application of project management and financial project appraisal techniques in a renewable energy context.




The shallow shelf seas that surround the continents are the oceans that we most interact with. They contribute a disproportionate amount to global marine primary production and CO2 drawdown into the ocean, and are important economically through commercial fisheries, offshore oil and gas exploration, and renewable energy developments (e.g. offshore wind farms). You will explore the physical processes that occur in shelf seas and coastal waters, their effect on biological, chemical and sedimentary processes, and how they can be harnessed to generate renewable energy. You will develop new skills during this module that will support careers in the offshore oil and gas industry, renewable energy industry, environmental consultancy, government laboratories (e.g. Cefas) and academia. The level of mathematical ability required to take this module is similar to Ocean Circulation and Meteorology I. You should be familiar with radians, rearranging equations and plotting functions.




In this module you will apply physics concepts and mathematical techniques to discover the astrophysics that govern the Universe at various scales, in both time and space. This includes stellar structure and evolution; stellar systems and populations; our Milky Way, other galaxies, and galactic systems; and the early Universe. You will also learn about the observational tools such as telescopes and detectors.




This module will build upon material covered in Meteorology I, by covering topics such as synoptic meteorology, weather hazards, micro-meteorology, further thermodynamics and weather forecasting. The module includes a major summative coursework assignment based on data collected on a UEA meteorology fieldcourse in a previous year.




Weather is one of the most popular topics of conversation. But how, specifically, does it present risks and opportunities, to people, organisations and to the wider environment? In this module you will develop a clear understanding of these linkages and an evidence base to draw on in future roles in which weather is a factor. You'll learn how to confidently source a diverse range of real-time weather information and you'll practice analysing such data, leading subsequently to successful interpretation and effective communication, both written and in front of the camera. You'll see, first hand, how meteorology depends upon computer systems for the efficient sharing, processing and visualisation of weather information. Being taught by weather practitioners with long experience of providing weather services to users, you will get the inside track on what it's like to work in weather. Weather Forecasting is one central theme and application which will provide a focus for learning. How are forecasts made and delivered, who uses forecasts and what are their distinctive needs? Success in forecasting depends in part on a good physical understanding of atmospheric processes - through practical work, we'll study those processes and use real examples of weather systems and events to reinforce the learning. At the end of the module, through an embedded week-long Easter residential fieldcourse, you'll apply your enhanced process understanding and forecasting knowledge in a hands-on way to design and implement meteorological field experiments, testing hypotheses through the collection and interpretation of field data collected using weather sensors. You'll write up your choice of fieldcourse experiment for assessment, after first receiving informal feedback on a related poster presentation.



Students will select 0 - 20 credits from the following modules:

Name Code Credits


On this module, you will study topics covering important areas of modern physical chemistry and chemical physics. The material will blend together experimental and theoretical aspects of photonics, condensed phase dynamics in molecular and macromolecular fluids and quantum and classical simulations.




This module will introduce you to key issues in mathematics education, particularly those that relate to the years of compulsory schooling. Specifically in this module we: Introduce the mathematics curriculum and pupils' perception of, and difficulties with, key mathematical concepts; Discuss public and popular culture perceptions of mathematics, mathematical ability and mathematicians as well as address ways in which these perceptions can be modified; Outline and discuss specific pedagogical actions (focused on challenge and motivation) that can be taken as early as possible during children's schooling and can provide a solid basis for pupils' understanding and appreciation of mathematics. By the end of the module you will be able to: Gain understanding of key curricular, pedagogical and social issues that relate to the teaching and learning of mathematics, a crucial subject area in the curriculum; Reflect on pedagogical action that aims to address those issues, particularly in the years of compulsory schooling; Be informed and able to consider the potential of pursuing a career in education, either as a teacher, educational professional or researcher in education with particular specialisation in the teaching and learning of mathematics.




What sets the mean global temperature of the world? Why are some parts of the world arid whilst others at the same latitudes are humid? This module aims to provide you with an understanding of the processes that determine why the Earth's climate (defined, for example, by temperature and moisture distribution) looks like it does, what the major circulation patterns and climate zones are and how they arise. You will study why the climate changes in time over different timescales, and how we use this knowledge to understand the climate systems of other planets. This module is aimed at you if you wish to further your knowledge of climate, or want a base for any future study of climate change, such as the Meteorology/Oceanography.




This module will provide you with an introduction to key areas of psychology with a focus on learning and teaching in education. By the end of the module you should be able to: - Discuss the role of perception, attention and memory in learning; - Compare and contrast key theories related to learning, intelligence, language, thinking and reasoning; - Critically reflect on key theories related to learning,intelligence, language, thinking and reasoning in the practical context; - Discuss the influence of key intrapersonal, interpersonal and situational factors on pupils learning and engagement in educational settings.




This module is highly practical and will allow you to study how electricity is generated and how it is distributed to users. The first part studies DC and AC electricity and looks at how RLC circuits behave through complex phasor analysis. The second part will give you the chance to study electricity generators, beginning with magnetism and Faraday's Law. Synchronous and asynchronous generators are studied along with application to conventional power stations and to renewable generation (e.g. wind). You'll also look at transformers and transmission lines with a view to distribution of electricity. Voltage conversion methods such as the rectifier, buck and boost converters are examined and finally electricity generation through solar is covered. Your lab classes will build on material from lectures which in turn forms the basis for coursework.




Geophysical hazards such as earthquakes, volcanic eruptions, tsunamis and landslides have significant environmental and societal impacts. This module focuses on the physical basis and analysis of each hazard, their global range of occurrence, probability of occurrence and their local and global impact. You will address matters such as hazard monitoring, modelling and assessment, and consider approaches towards risk mitigation and the reduction of vulnerability (individual and societal), with an emphasis on their practical implementation. Scenarios and probabilities of mega-disasters are also investigated. All the teaching faculty involved have practical experience of supplying professional advice on these hazards (and related risks) in addition to their own research involvement. A basic knowledge of physical science and of mathematics is assumed e.g. use of logs, exponentials, powers, cosines, rearrangement of equations.




Our aim is to show how environmental problems may be solved from the initial problem, to mathematical formulation and numerical solution. Problems will be described conceptually, then defined mathematically, then solved numerically via computer programming. The module consists of lectures on numerical methods and computing practicals; the practicals being designed to illustrate the solution of problems using the methods covered in lectures. We will guide you through the solution of a model of an environmental process of your own choosing. The skills developed in this module are highly valued by prospective employers.




This module is designed to introduce you to the psychological process underpinning motivated behaviour in education settings. You will examine the role of the teacher in creating motivational climates for learning and assessing some of the key motivational challenges that may occur in educational settings. What is motivated behaviour?; outcomes of motivated behaviour (e.g. effort, persistence, task choice); motivation through feelings of competence, confidence and control; motivational theories(e.g. attribution theory, expectancy-value theory, achievement goal theory, self-determination theory); interest and value; motivational climates (e.g. TARGET and autonomy-supportive); effects of rewards on motivation; motivational challenges (self-handicapping, procrastination, disengagement, learned helplessness, perfectionism); social influences; teacher-pupil relationship. The learning outcomes for this module are; a) Critically examine a range of intrapersonal, interpersonal and situational influences on motivation in education; b) Apply a range of motivational theories to understand motivated behaviour in education settings; c) Critically examine the role of the teacher in motivating students in educational settings: d) Understand how to overcome key motivational challenges, such as learned helplessness, self-handicapping, procrastination and disengagement in educational settings.




You will cover a selection of advanced topics in Physical Chemistry including statistical thermodynamics, reaction mechanisms and theories of reaction rates, photochemistry, electrochemistry and diffraction techniques.




You will gain an understanding of how science is disseminated to the public and explore the theories surrounding learning and communication. You will investigate science as a culture and how this culture interfaces with the public. Examining case studies in a variety of different scientific areas, alongside looking at how information is released in scientific literature and subsequently picked up by the public press, will give you an understanding of science communication. You will gain an appreciation of how science information can be used to change public perception and how it can sometimes be misinterpreted. You will also learn practical skills by designing, running and evaluating a public outreach event at a school or in a public area. If you wish to take this module you will be required to write a statement of selection. These statements will be assessed and students will be allocated to the module accordingly.




Whilst the University will make every effort to offer the modules listed, changes may sometimes be made arising from the annual monitoring, review and update of modules and regular (five-yearly) review of course programmes. Where this activity leads to significant (but not minor) changes to programmes and their constituent modules, there will normally be prior consultation of students and others. It is also possible that the University may not be able to offer a module for reasons outside of its control, such as the illness of a member of staff or sabbatical leave. In some cases optional modules can have limited places available and so you may be asked to make additional module choices in the event you do not gain a place on your first choice. Where this is the case, the University will endeavour to inform students.

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Entry Requirements

  • A Level BBB or ABC including Mathematics and Physics or BBC including Mathematics and Physics with an A in the Extended Project
  • International Baccalaureate 31 points including HL 5 in Mathematics and Physics
  • Scottish Highers AABBB including Mathematics and Physics
  • Scottish Advanced Highers CCC including Mathematics and Physics
  • Irish Leaving Certificate 2 subjects at H2, 4 at H3 including Mathematics and Physics
  • Access Course Pass Access to HE Diploma with Merit in 45 credits at Level 3 including 12 credits of Mathematics and 12 credits of Physics
  • BTEC Not accepted
  • European Baccalaureate 70% overall including 70% in Mathematics and Physics

Entry Requirement

GCSE English Language and Mathematics at Grade C/4 are required.

Science A-levels must include a pass in the practical element.

A-Level General Studies and Critical Thinking are not accepted.

UEA recognises that some students take a mixture of International Baccalaureate IB or International Baccalaureate Career-related Programme IBCP study rather than the full diploma, taking Higher levels in addition to A levels and/or BTEC qualifications. At UEA we do consider a combination of qualifications for entry, provided a minimum of three qualifications are taken at a higher Level. In addition some degree programmes require specific subjects at a higher level.

Students for whom English is a Foreign language

We welcome applications from students from all academic backgrounds. We require evidence of proficiency in English (including speaking, listening, reading and writing) at the following level:

IELTS: 6.5 overall (minimum 6.0 in any component)

We will also accept a number of other English language qualifications. Review our English Language Equivalences here.

INTO University of East Anglia 

If you do not yet meet the English language requirements for this course, INTO UEA offer a variety of English language programmes which are designed to help you develop the English skills necessary for successful undergraduate study:

Pre-sessional English at INTO UEA

English for University Study at INTO UEA

If you do not meet the academic and or English requirements for direct entry our partner, INTO University of East Anglia offers guaranteed progression on to this undergraduate degree upon successful completion of a preparation programme. Depending on your interests, and your qualifications you can take a variety of routes to this degree:

International Foundation in Physical Sciences and Engineering
International Foundation in Mathematics and Actuarial Sciences


The majority of candidates will not be called for an interview. However, for some students an interview will be requested. These are normally quite informal and generally cover topics such as your current studies, reasons for choosing the course and your personal interests and extra-curricular activities.

Gap Year

We welcome applications from students who have already taken or intend to take a gap year, believing that a year between school and university can be of substantial benefit. You are advised to indicate your reason for wishing to defer entry and may wish to contact the appropriate Admissions Office directly to discuss this further.


The School's annual intake is in September of each year.

Alternative Qualifications

We encourage you to apply if you have alternative qualifications equivalent to our stated entry requirements. Please contact us for further information.

Fees and Funding

Undergraduate University Fees and Financial Support

Tuition Fees

Information on tuition fees can be found here:

UK students

EU Students

Overseas Students

Scholarships and Bursaries

We are committed to ensuring that costs do not act as a barrier to those aspiring to come to a world leading university and have developed a funding package to reward those with excellent qualifications and assist those from lower income backgrounds. 

The University of East Anglia offers a range of Scholarships; please click the link for eligibility, details of how to apply and closing dates.

How to Apply

Applications need to be made via the Universities Colleges and Admissions Services (UCAS), using the UCAS Apply option.

UCAS Apply is a secure online application system that allows you to apply for full-time Undergraduate courses at universities and colleges in the United Kingdom. It is made up of different sections that you need to complete. Your application does not have to be completed all at once. The system allows you to leave a section partially completed so you can return to it later and add to or edit any information you have entered. Once your application is complete, it must be sent to UCAS so that they can process it and send it to your chosen universities and colleges.

The UCAS code name and number for the University of East Anglia is EANGL E14.

Further Information

Please complete our Online Enquiry Form to request a prospectus and to be kept up to date with news and events at the University. 

Tel: +44 (0)1603 591515


    Next Steps

    We can’t wait to hear from you. Just pop any questions about this course into the form below and our enquiries team will answer as soon as they can.

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