
Physics with Study Abroad MPhys
Department of Physics and Astronomy
Explore this course:
You are viewing this course for 2023-24 entry. 2022-23 entry is also available.
Key details
- A Levels AAA
Other entry requirements - UCAS code F305
- 4 years / Full-time
- September start
- Accredited
- Find out the course fee
- Study abroad
Course description
On this course, you’ll spend a year studying physics at a top university in the USA, Canada, New Zealand or Australia. It's a great way to get an even bigger range of perspectives on physics and where it can take you, while you experience life in another part of the world.
At the start of your course, you’ll cover the essential physics behind everything else you’ll study: heat, motion, electricity, magnetism and quantum mechanics. You’ll learn through lectures and practical labs so you won’t be learning about abstract topics in isolation. You’ll run experiments using the equipment in our modern laboratories to help you understand how important theories apply to the real world.
You’ll explore essential physics in even more depth in your second year, and choose from options where you can learn how stars and galaxies are structured, how particles are detected or the physics of music. Programming classes will teach you skills that are valuable in many graduate careers, from data science to computer game design.
Your third year will be your year abroad. When you return to Sheffield for your final year, you’ll have a variety of optional modules to choose from and you’ll work on a major research project. You’ll choose a research topic in physics and work closely with a member of academic staff who is an expert in the area you want to explore. The project takes up around half of your final year and can lead to a publication in a scientific journal.
Accredited by the Institute of Physics (IOP) for the purpose of fully meeting the educational requirement for Chartered Physicist.
Modules
A selection of modules are available each year - some examples are below. There may be changes before you start your course. From May of the year of entry, formal programme regulations will be available in our Programme Regulations Finder.
Choose a year to see modules for a level of study:
UCAS code: F305
Years: 2022, 2023
Core modules:
- Mathematics for Physicists and Astronomers
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This module provides the necessary level 1 mathematics for students taking physics and/or astronomy degrees. The following topics will be covered: basic algebra (functions, coordinate systems, algebraic manipulation etc), Taylor and binomial series, common functions of one variable, differentiation and integration techniques, basic complex numbers, first and second order differential equations, vector calculus, properties and applications of matrices and elementary probability theory.
30 credits - Fields and Quanta
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This module introduces the key concepts of fields and quanta: electric and magnetic fields, the behaviour of electric charges and currents, vectors and densities, potentials, quantum states and their evolution, the probabilistic nature of fundamental physical law, and the breakdown of classical physics. This module will teach you how physics problems relate to these fundamental concepts, and how those concepts are used to construct solutions.
25 credits - Motion and Heat
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This module introduces and applies the key concepts of motion and heat: force, equations of motion, phase space, determinism and free will, symmetry and conservation laws, waves and oscillations, coherence and classical frequency-time uncertainty, the laws of thermodynamics, thermal equilibrium, entropy and the arrow of time. You will learn how physics problems relate to these fundamental concepts, and how those concepts are used to construct solutions. You will apply the key concepts to design experiments to test scientific hypotheses. You will develop your data analysis and communication skills and to use different sources of information in your learning. You will work independently and as part of a group, developing a wide variety of study skills that will prepare you for the rest of your degree programme.
25 credits
Optional modules:
- Introduction to Astrophysics
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One of four half-modules forming the Level-1 Astronomy course, PHY104 aims to equip students with a basic understanding of the important physical concepts and techniques involved in astronomy with an emphasis on how fundamental results can be derived from fairly simple observations. The module consists of three sections:
10 credits
(i) Basic Concepts, Fluxes, Temperatures and Magnitudes;
(ii) Astronomical Spectroscopy;
(iii) Gravitational Astrophysics.
Parts (i), (ii) and (iii) each comprise some six lectures. The lectures are supported by problems classes, in which you will learn to apply lecture material to the solution of numerical problems. - The Solar System
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One of the four half-modules forming the Level 1 astronomy course, but may also be taken as a stand-alone module. PHY106 covers the elements of the Solar System: the Sun, planets, moons and minor bodies. What are their structures and compositions, and what dothey tell us about the formation and history of the Solar System?
10 credits - Our Evolving Universe
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The course provides a general overview of astronomy suitable for those with no previous experience of the subject. The principal topics covered are (1) how we deduce useful physical parameters from observed quantities, (2) the structure and evolution of stars, (3) the structure of the Milky Way, and the classification, structure and evolution of galaxies in general, (4) an introduction to cosmology and (5) extrasolar plantets and an introduction to astrobiology. All topics are treated in a descriptive manner with minimal mathematics.
10 credits - Frontiers of Physics
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This pair of 10-credit modules aims to introduce research-inspired material into the level 1 physics curriculum. Each module includes three short courses on research-based topics taught by an academic who is actively involved in the research. The individual courses will be regularly reviewed to ensure that the material is up to date and includes current areas of investigation. The module aims to show that cutting-edge physics research is often underpinned by basic concepts covered in A level and 1st year physics courses.
10 credits - The Physics of Sustainable Energy
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The module will cover the physics of sustainable energy. It includes discussions framed by the book `Sustainable Energy without the Hot Air' by D MacKay and will cover current energy requirements and what energy could potentially be provided by the various forms of renewable energy. The course will commence with a discussion of the basic physics of energy, power and work and the conversion of energy from one form to another. We examine in detail the history of global energy useage and how we produce and use energy in the UK. We will then explore the impacts that this energy use has on the biosphere and climate and the public perception of such processes. The course will then focus on the energy contenet of objects and processes we take for granted and will then move on to means by which we can produce energy using renewable technologies, such as wind, wave, solar, biofuels etc. We will also examine nuclear (fusion and fission) energy and will discuss their principles and practical implementation. Finally, we will consider solutions to our energy needs, including transportation, energy conservation, carbon capture and geoengineering.
10 credits - Physics of Living Systems 2
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The aim is to introduce biomechanical descriptions of the human body. We look at its structure and its performance as a physical machine. The structural characteristics of human bones and tissue are investigated, together with the mechanical functions of the skeleton and musculature. Simple fluid dynamic characteristics of the body are introduced, including descriptions of blood-flow in the arteries and veins and air-flow in the lungs.
10 credits - Introduction to Electric and Electronic Circuits
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This module introduces the concepts and analytical tools for predicting the behaviour of combinations of passive circuit elements, resistance, capacitance and inductance driven by ideal voltage and/or current sources which may be ac or dc sources. The ideas involved are important not only from the point of view of modelling real electronic circuits but also because many complicated processes in biology, medicine and mechanical engineering are themselves modelled by electric circuits. The passive ideas are extended to active electronic components; diodes, transistors and operational amplifiers and the circuits in which these devices are used. Transformers, magnetics and dc motors are also covered.
20 credits
Core modules:
- Classical and Quantum Physics
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This module provides the core level 2 physics content for non-theoretical degrees. It integrates physics content with supporting mathematics and practical work. Transferable skills are covered via different presentation modes for lab work. A further item is employability. The module also contains one or more items of group work. Physics topics covered are classical physics and oscillations, thermal physics, quantum mechanics, properties of matter and electromagnetism. Mathematics topics are Fourier techniques and partial differential equations. Both mathematical topics are applied to a range of the physics covered and are integrated with aspects of the practical work. The module is assessed via four standard exams (15% each), three topical and one integrative covering all the taught material, and course work (40%). Students must develop and pass a portfolio to pass the module.
70 credits - Programming in Python
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Teaching computer programming is a core aspect to our degree courses and is required by our accreditation body, the Institute of Physics. Python is a widely-available programming language that can be used to design powerful computer programmes suitable for scientific applications. In addition, Python is flexible, robust and is relatively easy to learn compared to other contemporary programming language. Python is also used widely in the computing industry and in research. The aim of this module is to teach the key elements of Python programming to enable students to design programs to perform tasks ranging from computational and numerical physics to data analysis and visualisation.
10 credits - Special Relativity & Subatomic Physics
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Special relativity is a key foundation of modern physics, particularly in the contexts of particle physics and astrophysics where E = mc2 and relativistic speeds are crucial concepts. In this module, the fundamental principles of special relativity will be explained, emphasising the energy-momentum four-vector and its applications to particle collisions and decays. Applications to nuclear physics include nuclear mass and binding energy, radioactive decay, nuclear reactions, nuclear fission and fusion. We will also cover the structure of the nucleus (liquid drop model and an introduction to the shell model).
10 credits
Optional modules:
- Aspects of Medical Imaging and Technology
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This module provides an introduction to medical technology, with a particular bias towards ionising and non-ionising electromagnetic radiation and its diagnostic role in medicine. The module begins with the generation and behaviour of electromagnetic waves and the breadth of technological application across the electomagnetic spectrum. This extends from magnetic resonance imaging at low energies to high energy photons in X-ray systems. The importance of radiation in diagnosis is acknowledged by discussion of imaging theory and primary imaging modalities, such as planar radiography and CT. The therapeutic role is examined by a brief consideration of radiotherapy.
10 credits - Astronomical Spectroscopy
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This level 2 module provides an overview of astronomical spectroscopy for astrophysics dual students, covering how spectrographs work, the nature of spectra, atomic physics relevant to astronomical spectroscopy, line broadening mechanisms (natural, pressure, thermal) and the Curve of Growth for the determination of ionic abundances in stellar atmospheres, plus spectral diagnostics of ionized nebulae. Content from lectures are reinforced through an exercise involving specialist astronomical software relating to nebular diagnostics, plus the manipulation of stellar spectroscopic datasets using the programming language Python for the calculation of ionic abundances.
10 credits - Galaxies
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This Level 2 Astronomy half-module aims to provide a comprehensive introduction to galaxies. It consists of six parts: (i) astronomical distance determination and galaxy classification; (ii) the properties of the main stellar and a gas components of our Milky Way galaxy, and its local environment; (iii) the properties of spiral galaxies; (iv) the properties of elliptical galaxies; (v) active galaxies; (vi) galaxy evolution. Students' presentation and research skills are developed through a 2500 word essay assignment.
10 credits - Physics of Materials
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This module provides an introduction to the physical properties of materials. Subjects covered include properties of liquids (surface tension, viscosity etc), solids (elastic properties, mechanical properties etc) and soft condensed matter.
10 credits - Stellar Structure and Evolution
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The module aims to provide an understanding of the physical processes occurring in stars and responsible for their internal structure and evolution from the main sequence to white dwarfs, neutron stars stars and black holes. It builds on Introduction to Astrophysics (PHY104) and seeks to explain the evolutionary phenomena described in Our Evolving Universe (PHY111).
10 credits - The Physics of Music
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This module will provide an introduction to the physics of music building on physics covered in year 1 and semester 2 of year 2. The module will include the following topics: Recap of oscillations, waves and resonance, the human voice, physics of tuned and untuned percussion, musical pitch and timbre, Fourier analysis, musical scales, physics of stringed instruments, physics of wind instruments, electric instruments (based on electro-magnetic pickups and piezoelectric transducers), synthesizers (analogue and digital), sound recording and reproduction (analogue and digital), myths, legends, folklore and pseudoscience in acoustics.
10 credits - Physics with Labview
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The module will teach Labview software, and allow students to experiment with instrumentation and basic electronics. These skills will be useful in further years of study, particularly with regard to the Level 3 and 4 projects. These skills are also useful in future employment in both academic and industrial science and engineering where being able to develop laboratory instrumentation to solve experimental problems will be highly desirable.
10 credits
You'll spend your third year studying physics abroad at one of our partner universities.
Core modules:
- Research project
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Students will undertake a supervised research project during the whole of the 4th year of an MPhys degree, applying their scientific knowledge to a range of research problems experimental and/or theoretical projects spanning the research expertise of the Department. Along with applying their knowledge, students will manage their project, ensuring that they develop skills in time management, project planning, scientific record keeping, information retrieval and analysis from scientific and other technical information sources.
60 credits
Optional modules:
- Advanced Particle Physics
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The main aim of the unit is to give a formal overview of modern particle physics. The mathematical foundations of Quantum Field Theory and of the Standard Model will be introduced. The theoretical formulation will be complemented by examples of experimental results from the Large Hadron Collider and Neutrino experiments. The unit aims to introduce students to the following topics:
10 credits
- A brief introduction to particle physics and a review of special relativity and quantum mechanics
- The Dirac Equation
- Quantum electrodynamics and quantum chromo-dynamics
- The Standard Model
- The Higgs boson
- Neutrino oscillations
- Beyond the Standard Model physics - Advanced Quantum Mechanics
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This module presents modern quantum mechanics with applications in quantum information and particle physics. After introducing the basic postulates, the theory of mixed states is developed, and we discuss composite systems and entanglement. Quantum teleportation is used as an example to illustrate these concepts. Next, we develop the theory of angular momentum, examples of which include spin and isospin, and the method for calculating Clebsch-Gordan coefficients is presented. Next, we discuss the relativistic extension of quantum mechanics. The Klein-Gordon and Dirac equations are derived and solved, and we give the equation of motion of a relativistic electron in a classical electromagnetic field. Finally, we explore some topics in quantum field theory, such as the Lagrangian formalism, scattering and Feynman diagrams, and modern gauge field theory.
10 credits - An Introduction to General Relativity
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This module introduces coordinate systems and transformations in Euclidean space. The principles of special relativity are reviewed, with emphasis on the coordinate transformations between systems moving at constant velocities. Our discussion of general relativity begins with an introduction to the principle of equivalence. We introduce the Christoffel symbols and the curvature tensors. We study examples of phenomena affected by general relativity, the rate of clocks and the redshift and bending of light in a gravitational field. Finally, we examine space time in the vicinity of the event horizon, the geometry of a non-spinning black hole, and the geometry of wormholes.
10 credits - Biological Physics
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This module will introduce students to biological physics, that is, the application of principles and tools from physics to biological systems. Biological materials are often soft condensed matter with properties between those of simple liquids and solids. In addition biological matter is usually out of equilibrium due to internal biochemical sources of energy. Students will begin to explore the world of biological cells and biopolymer macromolecules, such as DNA. They will see how physics can help understand biological systems through mathematical models and experimental imaging techniques and how this can lead to new physics and applications in biology.
10 credits - Dark Matter and the Universe
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Dark matter, though still unidentified and not yet directly detected, is established as a major constituent of the universe according to modern cosmology. In this course, we will review the astrophysical and cosmological evidence for the existence of dark matter, critically assess the various candidates that have been put forward, and discuss direct detection methods for the two most popular candidates: WIMPs and axions. The course has a multidisciplinary flavour combining work in astronomy, particle physics, solid state physics, detector technology and philosophy, encouraging development of skills in all these.
10 credits - Galaxy Formation and Evolution
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This module will cover one of the most exciting and fast moving topics in current astrophysics research, the formation and evolution of galaxies from an observational perspective. Starting with a brief historical introduction, the module will then summarise what we can learn about galaxy evolution from studies of galaxies in the local Universe, before discussing the results obtained from recent deep field observations of the high redshift Universe. The final part of the module will concern the important role that active galactic nuclei play in galaxy evolution.
10 credits - History of Astronomy
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The module aims to provide an introduction to the historical development of modern astronomy. After a brief chronological overview and a discussion of the scientific status of astronomy and the philosophy of science in general, the course is divided into a series of thematic topics addressed in roughly chronological order. We will focus on the nature of discovery in astronomy, in particular the interplay between theory and observation, the role of technological advances, and the relationship between astronomy and physics.
10 credits - Introduction to Cosmology
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The module will cover advanced astrophysics topics involving observations and theory of star and planet formation, plus the evolution of low, intermediate and high mass single stars, close binary evolution including their end states (white dwarfs, neutron stars, black holes), supernovae and gamma ray bursts.
10 credits - Magnetic Resonance: Principles and Applications
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The module will provide an overview of the basics of magnetic resonance, and then consider its applications in systems ranging from macroscopic living organisms, as in magnetic resonance imaging (MRI) widely used in hospitals, to nano-scale systems where control of single or a few spins is now possible and can also be used for nano-imaging. Special attention will be paid to recent advances in solid-state nano-NMR and the control of single electron spins in solid state nano-systems using spin resonance techniques.
10 credits - Optical Properties of Solids
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This course covers the optical physics of solid state materials. It begins with the classical description of optical propagation. It then covers the treatment of absorption and luminescence by quantum theory, and the modifications caused by excitonic effects. The phenomena are illustrated by discussing the optical properties of insulators, semiconductors, and metals. The infrared properties of ionic systems are then discussed, and the course concludes with a brief introduction to nonlinear crystals.
10 credits - Particle Astrophysics
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The LHC accelerates protons to kinetic energies of up to 7000 times their rest mass - a huge technological achievement. Yet, every second, over 500 million particles with energies greater than this collide with the Earth. Where do these particles come from, and how are they accelerated to these astonishing energies? These are, in fact, still open questions in astrophysics. In this module, we will look at the observational evidence for particle acceleration in astrophysical objects, the mechanisms available to accelerate particles, and some of the likely sources, including supernovae and supernova remnants, neutron stars, and active galaxies
10 credits - Physics Communication and Impact
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This module explores how physics ideas and concepts can be communicated to non-specialist audiences. We discuss how to design a communication, and the importance of knowing the purpose, message, and audience to pick the right medium and narrative. The main goal is to design your own communications to target particular audiences with a particular purpose and message. We will also discuss what impact is and how to assess it, analyse other people's communications, and consider aspects of communication, such as accessibility and some communication theory.
10 credits - Physics in an Enterprise Culture
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This is a seminar and workshop based course with a high level of student centred learning. The unit will introduce students to the methods and skills associated with innovation, business planning, costing and marketing. It will broaden students understanding of the mechanics of project planning and research commercialisation. The course is divided into two components:
10 credits
Part 1: Coming up with ideas. Students will take part in guest lectures and workshop classes to explore different ideas for business. They will learn about the innovation process and what makes a sucessful business. They will finish part 1 by submitting a draft business proposal that will be reviewed by academic staff and student peers and feedback will be given.
Part 2: Armed with the feedback from part 1 students will refine thier ideas and work towards a final pitch for thier business. Further support will be given to students to develop a costing of the idea. - Star Formation and Evolution
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The module will cover advanced astrophysics topics involving observations and theory of star and planet formation, plus the evolution of low, intermediate and high mass single stars, close binary evolution including their end states (white dwarfs, neutron stars, black holes), supernovae and gamma ray bursts.
10 credits - The Development of Particle Physics
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The module describes the development of several crucial concepts in particle physics, emphasising the role and significance of experiments. Students are encouraged to work from the original literature (the recommended text includes reprints of key papers). The module focuses not only on the particle physics issues involved, but also on research methodology - the design of experiments, the critical interpretation of data, the role of theory, etc. Topics covered include the discoveries of the neutron, the positron and the neutrino, experimental evidence for quarks and gluons, the neutral kaon system, CP violation etc.
10 credits - The Physics of Soft Condensed Matter
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Soft condensed matter is a generic name for a class of materials that play a crucial role in technology as well as providing fascinating and timely scientific problems. These complex materials are typified by polymers, gels and colloidal dispersions, whose properties often seem intermediate between ordinary liquids and solids. Familiar examples from everyday life include plastics, soaps and detergents, foodstuffs, and indeed the material from which living organisms are constructed. Only relatively recently has it been realised that despite the complexity of these materials elegant and simple physical principles often underlie their behaviour; this course provides an introduction to these principles.
10 credits
The content of our courses is reviewed annually to make sure it's up-to-date and relevant. Individual modules are occasionally updated or withdrawn. This is in response to discoveries through our world-leading research; funding changes; professional accreditation requirements; student or employer feedback; outcomes of reviews; and variations in staff or student numbers. In the event of any change we'll consult and inform students in good time and take reasonable steps to minimise disruption. We are no longer offering unrestricted module choice. If your course included unrestricted modules, your department will provide a list of modules from their own and other subject areas that you can choose from.
Learning and assessment
Learning
You'll learn through lectures, small group tutorials, programming classes, practical sessions in the lab and research projects.
Assessment
You will be assessed through a portfolio of problem sets, lab work and other material, as well as exams, essays, lab reports and presentations.
Programme specification
This tells you the aims and learning outcomes of this course and how these will be achieved and assessed.
Entry requirements
With Access Sheffield, you could qualify for additional consideration or an alternative offer - find out if you're eligible
The A Level entry requirements for this course are:
AAA
including Maths and Physics + pass in the practical element of any science A Levels taken
A Levels + additional qualifications AAB, including AA in Maths and Physics + A in a relevant EPQ
International Baccalaureate 36, with 6 in Higher Level Maths and Physics
BTEC Extended Diploma Not accepted
BTEC Diploma Not accepted
Scottish Highers + 2 Advanced Highers AAAAB + AA in Maths and Physics
Welsh Baccalaureate + 2 A Levels A + AA in Maths and Physics
Access to HE Diploma Award of Access to HE Diploma in Science, with 45 credits at Level 3, including 39 at Distinction (all in Maths and/or Physics units), and 6 at Merit
The A Level entry requirements for this course are:
AAB
including Maths and Physics + pass in the practical element of any science A Levels taken
A Levels + additional qualifications AAB, including AA in Maths and Physics + A in a relevant EPQ
International Baccalaureate 34, with 6, 5 in Higher Level Maths and Physics
BTEC Extended Diploma Not accepted
BTEC Diploma Not accepted
Scottish Highers + 2 Advanced Highers AAABB + AB in Maths and Physics
Welsh Baccalaureate + 2 A Levels B + AA in Maths and Physics
Access to HE Diploma Award of Access to HE Diploma in Science, with 45 credits at Level 3, including 39 at Distinction (all in Maths and/or Physics units), and 6 at Merit
You must demonstrate that your English is good enough for you to successfully complete your course. For this course we require: GCSE English Language at grade 4/C; IELTS grade of 6.5 with a minimum of 6.0 in each component; or an alternative acceptable English language qualification
Equivalent English language qualifications
Visa and immigration requirements
Other qualifications | UK and EU/international
If you have any questions about entry requirements, please contact the department.
Department of Physics and Astronomy

Scientists in the Department of Physics and Astronomy are working on topics such as how to build a quantum computer, the search for dark matter and ways to combat antimicrobial resistance. They run experiments on the Large Hadron Collider at CERN, and help to map the universe using the Hubble Space Telescope. They’ll guide you through the key topics in physics and give you a huge range of optional modules to choose from.
The department is based in the Hicks Building, which has recently refurbished undergraduate teaching laboratories with all the equipment you need for your physics and astronomy training, as well as classrooms, lecture theatres, computer rooms and social spaces for our students.
There are also telescopes and a solar technology testbed on the roof, state-of-the-art laboratories for building super-resolution microscopes and analysing 2D materials, and the UK’s first Quantum Information Laboratory, where students can study the fundamental science behind the next technological revolution. It’s right next door to the Students' Union, and just down the road from the 24/7 library facilities at the Information Commons and the Diamond.
Facilities
Our students are trained in newly refurbished teaching laboratories and can access a range of specialist technologies, from the telescopes on our roof to our state-of-the-art Quantum Information Laboratory.
In their final year, MPhys students are based in a specialist research laboratory where scientists are studying technologies such as 2D materials, photovoltaic devices and advanced microscopy tools.
Department of Physics and AstronomyWhy choose Sheffield?
The University of Sheffield
A top 100 university 2022
QS World University Rankings
92 per cent of our research is rated in the highest two categories
Research Excellence Framework 2021
No 1 Students' Union in the UK
Whatuni Student Choice Awards 2022, 2020, 2019, 2018, 2017
Department of Physics and Astronomy
Research Excellence Framework 2014
Graduate careers
Department of Physics and Astronomy
Our physics students develop numerical, problem solving and data analysis skills that are useful in many graduate jobs, including computer programming, software engineering, data science, and research and development into new products and services. Their expertise can be applied to many of the challenges and opportunities of the 21st century, from developing renewable energy technologies and improving medical treatments to creating quantum telecommunications systems and exploring outer space.
Students who want to work as a physics researcher often do a PhD, which can lead to a career at a top university or a major international research facility such as CERN.
The University of Sheffield is part of the White Rose Industrial Physics Academy. This partnership of university physics departments and technical industries can set up collaborations between our students and industrial partners through internships, year in industry placements, final year projects and careers activities. WRIPA also organises the UK’s largest physics recruitment fair, where our students can meet potential employers.
Fees and funding
Fees
Additional costs
The annual fee for your course includes a number of items in addition to your tuition. If an item or activity is classed as a compulsory element for your course, it will normally be included in your tuition fee. There are also other costs which you may need to consider.
Funding your study
Depending on your circumstances, you may qualify for a bursary, scholarship or loan to help fund your study and enhance your learning experience.
Use our Student Funding Calculator to work out what you’re eligible for.
Additional funding
The University of Sheffield’s Experience Sheffield Scholarships includes a number of scholarships that are guaranteed to go to students in the Department of Physics and Astronomy.
Visit us
University open days
There are four open days every year, usually in June, July, September and October. You can talk to staff and students, tour the campus and see inside the accommodation.
Taster days
At various times in the year we run online taster sessions to help Year 12 students experience what it is like to study at the University of Sheffield.
Applicant days
If you've received an offer to study with us, we'll invite you to one of our applicant days, which take place between November and April. These applicant days have a strong department focus and give you the chance to really explore student life here, even if you've visited us before.
Campus tours
Campus tours run regularly throughout the year, at 1pm every Monday, Wednesday and Friday.
Apply for this course
Make sure you've done everything you need to do before you apply.
How to apply When you're ready to apply, see the UCAS website:
www.ucas.com
Not ready to apply yet? You can also register your interest in this course.
Contact us
Telephone: +44 114 222 4362
Email: physics.ucas@sheffield.ac.uk
The awarding body for this course is the University of Sheffield.
Recognition of professional qualifications: from 1 January 2021, in order to have any UK professional qualifications recognised for work in an EU country across a number of regulated and other professions you need to apply to the host country for recognition. Read information from the UK government and the EU Regulated Professions Database.