About this course

This specialist astrophysics course offers an unrivalled opportunity to study astrophysics with a year abroad. You'll spend your fourth year on a research project at the prestigious Harvard-Smithsonian Center for Astrophysics (CfA) in Boston, USA. We are the only UK university that partners with Harvard in this way.

This flagship course is offered to the best University of Southampton astrophysics students studying our MPhys Physics with Astronomy degree at the end of year 2.

Another feature is a 2-week field trip to Tenerife where you’ll take part in a space mission design project.

You’ll also spend a week at an observatory learning to use high-spec telescopes.

As part of your astrophysics degree, you’ll develop an in-depth understanding of:

the make-up, dynamics and environment of galaxies
the life cycle of stars
how radiation is produced and detected in a cosmic setting
the space environment and space weather
concepts of modern cosmology, including the nature of dark matter

You’ll also learn the science behind powerful phenomena such as white dwarfs, black holes and neutron stars, the evolution of the universe, the formation of galaxies and space weather.

Course location

This course is based at Highfield.

Awarding body

This qualification is awarded by the University of Southampton.

Download the Course Description Document

The Course Description Document details your course overview, your course structure and how your course is taught and assessed.

Changes due to COVID-19

Although the COVID-19 situation is improving, any future restrictions could mean we might have to change the way parts of our teaching and learning take place in 2021 to 2022. We're working hard to plan for a number of possible scenarios. This means that some of the information on this course page may be subject to change.

Find out more on our COVID advice page.

ODT

Download 2021-22 Course Description Document

Entry requirements

Select the academic year you want to see entry requirements for

A-levels

AAA-AAB including grades AA in mathematics/further mathematics and physics, with a pass in the physics Practical
or
AABC including grades AA in mathematics/further mathematics and physics, with a pass in the physics Practical

A-levels additional information

Offers typically exclude General Studies and Critical Thinking. Successful applicants will be invited to visit the department and attend an optional interview; the optional interview could lead to a lower offer.

More information about A-levels

A-levels with Extended Project Qualification

If you are taking an EPQ in addition to 3 A levels, you will receive the following offer in addition to the standard A level offer:

AAB including mathematics/further mathematics (minimum grade A) and physics (minimum grade A), with a pass in the physics Practical, plus grade A in the EPQ

A-levels contextual offer

We are committed to ensuring that all applicants with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise an applicant's potential to succeed in the context of their background and experience.

Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.

BTEC

D in the BTEC National Extended Certificate plus grades AA in A-level mathematics/further mathematics and physics, with a pass in the physics Practical

We do not accept the BTEC National Extended Diploma.

We do not accept the BTEC National Diploma.

Applicants with a BTEC National Extended Diploma or the BTEC National Diploma should apply for the Engineering/Physics/Mathematics/Geophysics Foundation Year

RQF BTEC

We are committed to ensuring that all learners with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise a learner’s potential to succeed in the context of their background and experience.
Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.

Additional information

The University aims to recruit students from a wide range of backgrounds who we believe have the potential and motivation to succeed on our challenging programmes. We are committed to fair admissions and strive to ensure we give equal consideration to all applicants who possess the necessary knowledge and skills.

More information about BTEC

QCF BTEC

D in the BTEC Subsidiary Diploma plus grades AA in A-level mathematics/further mathematics and physics, with a pass in the physics Practical

We do not accept the BTEC Diploma

We do not accept the BTEC Extended Diploma

Applicants with a BTEC Extended Diploma or the BTEC Diploma should apply for the Engineering/Physics/Mathematics/Geophysics Foundation Year

We are committed to ensuring that all learners with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise a learner’s potential to succeed in the context of their background and experience. Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.

Select additional entry requirements to display

Other requirements

UK students

International students

Other ways to qualify

GCSE requirements

Applicants must hold GCSE English language (or GCSE English) (minimum grade 4/C) and mathematics (minimum grade 4/C)

A-levels

AAA-AAB including grades AA in mathematics or further mathematics and physics, with a pass in the physics Practical (where it is separately endorsed) or AABC including grades AA in mathematics or further mathematics and physics, with a pass in the physics Practical (where it is separately endorsed)

A-levels additional information

Offers typically exclude General Studies and Critical Thinking. Successful applicants will be invited to visit the department and attend an optional interview. The optional interview may lead to a reduced offer. Applicants who have not studied mathematics/further mathematics and/or physics at A-level can apply for the Engineering/Physics/Mathematics Foundation Year. Please visit theFoundation Year page for more information.

More information about A-levels

A-levels with Extended Project Qualification

If you are taking an EPQ in addition to 3 A levels, you will receive the following offer in addition to the standard A level offer: AAB including mathematics or further mathematics (minimum grade A) and physics (minimum grade A), with a pass in the physics Practical (where it is separately endorsed) plus grade A in the EPQ

A-levels contextual offer

We are committed to ensuring that all applicants with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise an applicant's potential to succeed in the context of their background and experience. Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.

BTEC

D in the BTEC National Extended Certificate plus grades AA in A-level mathematics or further mathematics and physics, with a pass in the physics Practical (where it is separately endorsed) We will consider the BTEC National Extended Diploma if studied alongside A-levels in mathematics/further mathematics and physics We will consider the BTEC National Diploma if studied alongside A-levels in mathematics/further mathematics and physics

RQF BTEC

We are committed to ensuring that all learners with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise a learner’s potential to succeed in the context of their background and experience. Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.

Additional information

Applicants who have not studied the required subjects at A-level can apply for the Engineering/Physics/Mathematics Foundation Year. Please visit theFoundation Year page for more information.

More information about BTEC

QCF BTEC

D in the BTEC Subsidiary Diploma plus grades AA in A-level mathematics or further mathematics and physics, with a pass in the physics Practical (where it is separately endorsed) We will consider the BTEC Extended Diploma if studied alongside A-levels in mathematics/further mathematics and physics We will consider the BTEC Diploma if studied alongside A-levels in mathematics/further mathematics and physics

We are committed to ensuring that all learners with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise a learner’s potential to succeed in the context of their background and experience. Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.

Select additional entry requirements to display

Welsh Baccalaureate

AAA-AAB including grades AA in mathematics or further mathematics and physics, with a pass in the physics Practical (where it is separately endorsed) or AA from two A-levels including mathematics or further mathematics and physics, with a pass in the physics Practical (where it is separately endorsed) and A-B from the Advanced Welsh Baccalaureate Skills Challenge Certificate or AABC including grades AA in mathematics or further mathematics and physics, with a pass in the physics Practical (where it is separately endorsed) or AA from two A-levels including mathematics or further mathematics and physics, with a pass in the physics Practical (where it is separately endorsed), and grades BC from a third A-level and the Advanced Welsh Baccalaureate Skills Challenge Certificate

Welsh Baccalaureate additional information

Welsh Baccalaureate contextual offer

We are committed to ensuring that all learners with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise a learner’s potential to succeed in the context of their background and experience. Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.

Other requirements

UK students

International students

Other ways to qualify

GCSE requirements

Applicants must hold GCSE English language (or GCSE English) (minimum grade 4/C) and mathematics (minimum grade 4/C)

Got a question?

Please contact our enquiries team if you're not sure that you have the right experience or qualifications to get onto this course.

Email: enquiries@southampton.ac.uk
Tel: +44(0)23 8059 5000

Course structure

You don’t need to choose your modules when you apply. Your academic tutor will help you to customise your course.

On this degree in astrophysics you’ll gain a robust understanding of core physics concepts and practical lab skills, while developing your knowledge of astronomy and astrophysics to an advanced level.

After transferring at the end of year 2, the third year is carefully coordinated to cover all the core physics and astronomy modules. This means you can spend year 4 focused on your research project at the Harvard-Smithsonian Center for Astrophysics (CfA).

Right from the start you’ll apply and develop your analytical and problem-solving skills on mini-projects in the lab. You’ll also use our on-site observatory and telescopes to collect and analyse astronomical data.

Year 1 overview

This consists of core modules on the key principles of physics and experimentation.

These include topics on:

physics skills
mathematics
waves and light
energy and matter
motion and relativity
electricity and magnetism

You’ll also take an introductory module on astronomy and space science to prepare you for your specialist astronomy studies.

Year 2 overview

Core modules include topics on:

electromagnetism
quantum physics
mechanics
wave physics
galaxies

You can also choose from a range of optional modules on topics like:

equations
medical physics
practical photonics
energy in the environment

Year 3 overview

Core modules in year 3 cover topics on:

atomic physics
photons in astrophysics
nuclei and particles
theories of matter
space and time
stellar evolution

You’ll also do an individual dissertation.

Year 4 overview

In your final year, you’ll relocate to the Center for Astrophysics (CfA)

This combines the resources of the Harvard College Observatory and the Smithsonian Astrophysical Observatory to study the basic physical processes that determine the nature and evolution of the universe.

You’ll work alongside a CfA researcher on an agreed topic of astrophysics. These include star and planet formation, cosmology and extreme astronomical objects.

You’ll do a significant research project resulting in a thesis, ideally of publishable quality, under the guidance of a supervisor from the Harvard-Smithsonian Astrophysical Observatory.

Want more detail? See all the modules in the course.

Modules

Changes due to COVID-19

Find out more on our COVID advice page.

For entry in Academic Year 2022-23

Year 1

Year 2

Year 3

Year 4

You must study the following modules in year 1:

Electricity and Magnetism

The major concepts covered are: - The abstraction from forces to fields using the examples of the electric and magnetic fields, with some applications - The connection between conservative forces and potential energy - How charges move through electri...

Energy and Matter

This course introduces the ideas of thermal physics, contrasting the complexity of a world composed of huge numbers of sub-microscopic particles with the simplicity of the thermodynamic laws that govern its large-scale behaviour.

Introduction to Astronomy and Space Science

The module shows how simple physical principles can be used to learn about the Universe. The focus is upon how one can measure physical quantities such as size, distance, temperature, age and mass for the variety of objects in the Universe. By its end stu...

Mathematical Methods For Physical Scientists 1b

To provide students with the necessary skills and confidence to apply a range of mathematical methods to problems in the physical sciences. We build on the methods developed in MATH1006 (or MATH1008) but extend many of the ideas from ordinary functions to...

Mathematical Methods for Physical Scientists 1a

To provide students with the necessary skills and confidence to apply a range of mathematical methods to problems in the physical sciences. Both MATH1006 and MATH1008 cover essentially the same topics in calculus that are of relevance to applications in t...

Motion and Relativity

The first part of the module focuses on Newton’s laws of motion, potentials, conservation of energy, momentum and angular momentum, projectiles, circular motion, gravity and simple harmonic motion including damping. The second part of the module is an ...

Physics Skills - Programming and Data Analysis

The primary goal is to provide students with the practical programming and data analysis skills that are necessary for both their degree course and most careers in physics. Python is used as the introductory programming language, and numerical simulations...

Physics Skills 1

The Physics Skills units develop a range of skills needed by a professional physicist, including facility in conducting experiments and in analysing and reporting their results. Physics Skills 1 runs in first semester and its companion Physics Skills 2 (P...

Physics Skills 2

Waves, Light and Quanta

It will arm students with a basic knowledge of optics, including ray propagation, polarization and diffraction, and introduce the dual wave and particle characteristics of light and matter. It provides a base for further study of optics, wave physics and ...

You must study the following modules in year 2:

Classical Mechanics

Beginning with a review of Newton's Laws applied to systems of particles, the course moves on to rotational motion, dynamical gravity (Kepler's Laws) and motion in non-inertial reference frames. Systems of coupled oscillators are studied.

Design and Observation in Astronomy

The course takes place during the Easter vacation at La Laguna University, Tenerife, Spain. The course consists of two separately assessed modules. Module 1 is a one week design study of an astronomical spacecraft. Module 2 is a week of practical o...

Electromagnetism

Electromagnetism is one of the brilliant successes of nineteenth century physics and the equations formulated by Maxwell are believed to account exactly for all classical electromagnetic phenomena. The aim of this course is to present the laws of elect...

Galaxies

We will start from outlining fundamental questions we must answer in order to build up a picture of an astrophysical object, e.g., what is it made of? How luminous? How big? How old? How fast? How heavy? These seemingly simple questions are surprisingly d...

Physics from Evidence I

The PHYS2022 Physics from Evidence I module consists of three parts: Teaching Lab, Computing Module and Student Conference. The Teaching Lab and Computing Modules run through the first 10 weeks of the semester and the Student Conference is in week 12.

Quantum Physics

After studying this course students should be able to explain the concept of quantum mechanical wave function and its basic properties, the Schrödinger equation, the concepts of operator, eigenstates and the significance of measurements, and describe the ...

Statistical Mechanics

Statistical mechanics links the microscopic properties of physical systems to their macroscopic properties. Thermodynamics, which describes macroscopic properties, can then be derived from statistical mechanics with a few well motivated postulates. It lea...

Wave Physics

This course introduces the properties and mechanics of waves, from the derivation and solution of wave equations, through the origins of the classical processes of refraction, dispersion and interference, to the quantum mechanical phenomenon of the uncert...

You must study the following modules in year 3:

Atomic Physics

The aim of this course is to apply quantum physics to the study of atoms.

Computer Techniques in Physics

This Computational Physics course is designed for students with definite interest in tackling physics problems that are only tractable through the use of computers. It covers all types of application of computers by physicists, except the control of equip...

Cosmology

Modern cosmology is a fascinating and fast-developing field, with intense research activity fuelled by major discoveries made in the last decade. These have overturned our understanding of the Universe’s properties and established a new standard cosmologi...

Crystalline Solids

This course builds upon the Statistical Mechanics Course (PHYS2024) to form a complete basic course on the fundamentals of the physics of solids. After the course the student should have developed the necessary theoretical knowledge to enable them to unde...

Nuclei and Particles

Students will learn about Nuclear Scattering, various properties of Nuclei, the Liquid Drop Model and the Shell Model, radioactive decay, fission and fusion. By the end of the course, the students should be able to classify elementary particles into hadro...

Photons in Astrophysics

The main radiation mechanisms are discussed and examples are given of the situations in which they are most important. We show how the physical conditions, e.g. the temperature, density and magnetic field strength, can be determined from the emitted radia...

Stellar Evolution

This course is a showcase for how the various branches of physics come together to give rise to real life phenomena. Using the example of stars, we will revisit a wide range of different physics and see how the various ingredients interact and thus how al...

Theories of Matter, Space and Time

Variational methods in classical physics will be reviewed and the extension of these ideas in quantum mechanics will be introduced.

Learning and assessment

The learning activities for this course include the following:

lectures
classes and tutorials
coursework
individual and group projects
independent learning (studying on your own)

How you'll spend your course time:

Year 1

Year 2

Year 3

Year 4

Study time

Your scheduled learning, teaching and independent study for year 1:

39%

Scheduled learning & teaching

61%

Independent learning

How we'll assess you

coursework, laboratory reports and essays
design and problem-solving exercises
individual and group projects
oral presentations
written and practical exams

Your assessment breakdown

Year 1:

44%

Written exam

38%

Coursework

18%

Practical exam

Academic support

You’ll be supported by a personal academic tutor and have access to a senior tutor.

Course leader

Diego Altamirano is the course leader.

Careers

This degree is the perfect preparation for a PhD and onward to a astrophysics career as a professional astronomer. However, it is also an eye-catching addition to your CV if you wish go directly into a different career.

Potential roles include:

astrophysicist
professional astronomer
data analyst
government science policy officer
medical physicist
satellite engineer
systems analyst
weather forecaster

If you decide on a career outside physics, you’ll be able to demonstrate transferable skills such as computation and coding, statistical analysis, communication and project management skills.

We work hard to help you get the career of your choice and make the process easier and more enjoyable.

During year 2 you’ll have access to a programme of physics-focused career sessions, timetabled to fit in with your studies. These include application and interview workshops and talks from visiting professionals.

We can help you find a paid summer placement to give you valuable hands-on experience and the chance to make industry contacts.

If you’d like to gain extra astronomy research experience, you could do your placement in our labs, working alongside graduate students on an Astronomy Research Group project.

Careers services at Southampton

We are a top 20 UK university for employability (QS Graduate Employability Rankings 2019). Our Careers and Employability Service will support you throughout your time as a student and for up to 5 years after graduation. This support includes:

work experience schemes
CV and interview skills and workshops
networking events
careers fairs attended by top employers
a wealth of volunteering opportunities
study abroad and summer school opportunities

We have a vibrant entrepreneurship culture and our dedicated start-up supporter, Futureworlds, is open to every student.

Fees, costs and funding

Tuition fees

Fees for a year's study:

UK students pay £9,250.
EU and international students pay £23,720.

What your fees pay for

Your tuition fees pay for the full cost of tuition and all examinations.

Find out how to:

Accommodation and living costs, such as travel and food, are not included in your tuition fees. Explore:

Bursaries, scholarships and other funding

If you're a UK or EU student and your household income is under £25,000 a year, you may be able to get a University of Southampton bursary to help with your living costs. Find out about bursaries and other funding we offer at Southampton.

If you're a care leaver or estranged from your parents, you may be able to get a specific bursary.

Get in touch for advice about student money matters.

Scholarships and grants

You may be able to get a scholarship or grant that's linked to your chosen subject area.

We award scholarships and grants for travel, academic excellence, or to students from underrepresented backgrounds.

Support during your course

The Student Services Centre offers support and advice on money to students. You may be able to access our Student Support fund and other sources of financial support during your course.

Funding for EU and international students

Find out about funding you could get as an international student.

Astrophysics with Year Abroad (MPhys)

About this course

Course location

Awarding body

Download the Course Description Document

Changes due to COVID-19

Entry requirements

For Academic year 202223

A-levels

A-levels additional information

A-levels with Extended Project Qualification

A-levels contextual offer

BTEC

RQF BTEC

Additional information

QCF BTEC

Access to HE Diploma

Access to HE additional information

Irish Leaving Certificate

Irish Leaving Certificate (first awarded 2017)

Irish Leaving Certificate (first awarded 2016)

Irish certificate additional information

Scottish Qualification

Cambridge Pre-U

Cambridge Pre-U additional information

Welsh Baccalaureate

Welsh Baccalaureate additional information

Welsh Baccalaureate contextual offer

European Baccalaureate

Other requirements

GCSE requirements

English language requirements

IELTS score requirements

For Academic year 202324

A-levels

A-levels additional information

A-levels with Extended Project Qualification

A-levels contextual offer

BTEC

RQF BTEC

Additional information

QCF BTEC

Access to HE Diploma

Access to HE additional information

Irish Leaving Certificate

Irish Leaving Certificate (first awarded 2017)

Irish Leaving Certificate (first awarded 2016)

Irish certificate additional information

Scottish Qualification

Cambridge Pre-U

Cambridge Pre-U additional information

Welsh Baccalaureate

Welsh Baccalaureate additional information

Welsh Baccalaureate contextual offer

European Baccalaureate

Other requirements

GCSE requirements

Got a question?

Course structure

Year 1 overview

Year 2 overview

Year 3 overview

Year 4 overview

Modules

Changes due to COVID-19

For entry in Academic Year 2022-23

Year 1 modules

Year 2 modules

Year 3 modules

Year 4 modules

Learning and assessment

Course time

Year 1

Study time

How we'll assess you

Your assessment breakdown

Year 2

Study time

How we'll assess you

Your assessment breakdown