About this course
Fuel your fascination for space and the technologies used to investigate it. On this MPhys Physics with Space Science degree you’ll explore a wide range of subjects, from the essentials of astronomy through to satellite design and space weather. You’ll also benefit from the latest research.
With the global space market set to almost double by 2030, your skills will be in high demand. This degree will also prepare you for further study at PhD level.
You’ll examine phenomena that can only be monitored from space, such as geomagnetic storms and solar wind, and combine your physics knowledge with space engineering principles to learn about spacecraft design.
A Tenerife study trip is another high point. Working as part of an international and interdisciplinary team, you’ll design a space-based telescope and its instrumentation, and plan its launch.
Throughout your degree you’ll study the core physics subjects of the Masters degree course, but with an emphasis on space science.
The course is accredited by the Institute of Physics.
Physics offers an academic scholarship worth up to £20,000, based on submission of a short essay and an interview at one of our applicant visit days.
We regularly review our courses to ensure and improve quality. This course may be revised as a result of this. Any revision will be balanced against the requirement that the student should receive the educational service expected. Find out why, when, and how we might make changes.
Our courses are regulated in England by the Office for Students (OfS).
Accreditations
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.
Entry requirements
For Academic year 202526
A-levels
A*AA-AAA including physics (minimum grade A) and either mathematics or further mathematics (minimum grade A)
or
AABB-AABC including physics (minimum grade A) and either mathematics or further mathematics (minimum grade A)
A-levels additional information
Successful applicants will be invited to visit the department and attend an optional interview. The optional interview may lead to a lower offer.
A pass in the science Practical is required where it is separately endorsed.
Offers typically exclude General Studies and Critical Thinking.
Applicants who have not studied mathematics/further mathematics and/or physics at A-level can apply for the Engineering/Physics/Mathematics Foundation Year
A-levels with Extended Project Qualification
If you are taking an EPQ in addition to three A levels, you will receive the following offer in addition to the standard A level offer: AAA including physics (minimum grade A) and either mathematics or further mathematics (minimum grade A), plus grade A in the EPQ
A-levels 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.
International Baccalaureate Diploma
Pass, with 38-36 points overall, with 19-18 points required at Higher Level, including 6 at Higher Level in mathematics (Analysis and Approaches or Applications and Interpretation) and 6 at Higher Level in physics
International Baccalaureate Diploma additional information
Successful applicants will be invited to visit the department and attend an optional interview. The optional interview may lead to a lower offer.
Applicants who have not studied mathematics and/or physics at Higher Level can apply for the Engineering/Physics/Mathematics Foundation Year
International 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.
International Baccalaureate Career Programme (IBCP) statement
Offers will be made on the individual Diploma Course subject(s) and the career-related study qualification. The CP core will not form part of the offer. Where there is a subject pre-requisite(s), applicants will be required to study the subject(s) at Higher Level in the Diploma course subject and/or take a specified unit in the career-related study qualification. Applicants may also be asked to achieve a specific grade in those elements. Please see the University of Southampton International Baccalaureate Career-Related Programme (IBCP) Statement for further information. Applicants are advised to contact their Faculty Admissions Office for more information.
BTEC
D*-D in the BTEC National Extended Certificate plus grades AA-A*A in A-level physics and A-level mathematics or further mathematics.
We will consider the BTEC National Diploma if it has been studied alongside A-levels in mathematics/further mathematics and physics.
We will consider the BTEC National Extended Diploma if it has been 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 can apply for the Engineering/Physics/Mathematics Foundation Year
QCF BTEC
D*-D in the BTEC Subsidiary Diploma plus grades AA-A*A in A-level physics and A-level mathematics or further mathematics.
We will consider the BTEC Extended Diploma if it has been studied alongside A-levels in mathematics/further mathematics and physics.
We will consider the BTEC Diploma if it has been 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.
Access to HE Diploma
Not accepted for this course. Applicants with an Access to HE Diploma in a relevant subject should apply for the Engineering/Physics/Mathematics Foundation Year
Irish Leaving Certificate
Irish Leaving Certificate (first awarded 2017)
H1,H1,H1,H2,H2,H2- H1,H1,H2,H2,H2,H2 including mathematics, applied mathematics and physics
Irish certificate additional information
Successful applicants will be invited to visit the department and attend an optional interview. The optional interview may lead to a lower offer. Applicants who have not studied mathematics and/or physics can apply for the Engineering/Physics/Mathematics Foundation Year
Scottish Qualification
Offers will be based on exams being taken at the end of S6. Subjects taken and qualifications achieved in S5 will be reviewed. Careful consideration will be given to an individual’s academic achievement, taking in to account the context and circumstances of their pre-university education.
Please see the University of Southampton’s Curriculum for Excellence Scotland Statement (PDF) for further information. Applicants are advised to contact their Faculty Admissions Office for more information.
Cambridge Pre-U
D2 D3 D3 - D3 D3 D3 in three Principal subjects including physics (minimum grade D3) and either mathematics or further mathematics (minimum grade D3)
Cambridge Pre-U additional information
Cambridge Pre-U's can be used in combination with other qualifications such as A Levels to achieve the equivalent of the typical offer, where D3 can be used in lieu of A Level grade A or grade M2 can be used in lieu of A Level grade B.
Successful applicants will be invited to visit the department and attend an optional interview. The optional interview may lead to a lower offer.
Applicants who have not studied the required Principal subjects can apply for the Engineering/Physics/Mathematics Foundation Year
Welsh Baccalaureate
A*AA-AAA including physics (minimum grade A) and either mathematics or further mathematics (minimum grade A)
or
A*A-AA from two A-levels including physics and either mathematics or further mathematics and A from the Advanced Welsh Baccalaureate Skills Challenge Certificate
or
AAAB-AABB including physics (minimum grade A) and either mathematics or further mathematics (minimum grade A)
or
AA from two A-levels including physics and either mathematics or further mathematics, plus grades AB-BB from a third A-level and the Advanced Welsh Baccalaureate Skills Challenge Certificate
Welsh Baccalaureate additional information
Successful applicants will be invited to visit the department and attend an optional interview. The optional interview may lead to a lower offer.
A pass in the science Practical is required where it is separately endorsed.
Offers typically exclude General Studies and Critical Thinking.
Applicants who have not studied mathematics/further mathematics and/or physics at A-level can apply for the Engineering/Physics/Mathematics Foundation Year
Welsh Baccalaureate 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.
T-Level
Not accepted for this course. Applicants with a T level Technical Qualification in a relevant subject can apply for the Engineering/Physics/Mathematics Foundation Year
Other requirements
GCSE requirements
Applicants must hold GCSE English language (or GCSE English) (minimum grade 4/C) and mathematics (minimum grade 4/C)
Find the equivalent international qualifications for our entry requirements.
English language requirements
If English isn't your first language, you'll need to complete an International English Language Testing System (IELTS) to demonstrate your competence in English. You'll need all of the following scores as a minimum:
IELTS score requirements
- overall score
- 6.5
- reading
- 6.0
- writing
- 6.0
- speaking
- 6.0
- listening
- 6.0
We accept other English language tests. Find out which English language tests we accept.
If you don’t meet the English language requirements, you can achieve the level you need by completing a pre-sessional English programme before you start your course.
You might meet our criteria in other ways if you do not have the qualifications we need. Find out more about:
- our Ignite your Journey scheme for students living permanently in the UK (including residential summer school, application support and scholarship)
- skills you might have gained through work or other life experiences (otherwise known as recognition of prior learning)
Find out more about our Admissions Policy.
For Academic year 202425
A-levels
A*AA-AAA including physics (minimum grade A) and either mathematics or further mathematics (minimum grade A)
or
AABB-AABC including physics (minimum grade A) and either mathematics or further mathematics (minimum grade A)
A-levels additional information
Successful applicants will be invited to visit the department and attend an optional interview. The optional interview may lead to a lower offer.
A pass in the science Practical is required where it is separately endorsed.
Offers typically exclude General Studies and Critical Thinking.
Applicants who have not studied mathematics/further mathematics and/or physics at A-level can apply for the Engineering/Physics/Mathematics Foundation Year
A-levels with Extended Project Qualification
If you are taking an EPQ in addition to three A levels, you will receive the following offer in addition to the standard A level offer: AAA including physics (minimum grade A) and either mathematics or further mathematics (minimum grade A), 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, as follows: AAA or AABC including physics (minimum grade A) and either mathematics or further mathematics (minimum grade A)
International Baccalaureate Diploma
Pass, with 38-36 points overall, with 19-18 points required at Higher Level, including 6 at Higher Level in mathematics (Analysis and Approaches or Applications and Interpretation) and 6 at Higher Level in physics
International Baccalaureate Diploma additional information
Successful applicants will be invited to visit the department and attend an optional interview. The optional interview may lead to a lower offer.
Applicants who have not studied mathematics and/or physics at Higher Level can apply for the Engineering/Physics/Mathematics Foundation Year
International 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.
International Baccalaureate Career Programme (IBCP) statement
Offers will be made on the individual Diploma Course subject(s) and the career-related study qualification. The CP core will not form part of the offer. Where there is a subject pre-requisite(s), applicants will be required to study the subject(s) at Higher Level in the Diploma course subject and/or take a specified unit in the career-related study qualification. Applicants may also be asked to achieve a specific grade in those elements. Please see the University of Southampton International Baccalaureate Career-Related Programme (IBCP) Statement for further information. Applicants are advised to contact their Faculty Admissions Office for more information.
BTEC
D*-D in the BTEC National Extended Certificate plus grades AA-A*A in A-level physics and A-level mathematics or further mathematics.
We will consider the BTEC National Diploma if it has been studied alongside A-levels in mathematics/further mathematics and physics.
We will consider the BTEC National Extended Diploma if it has been 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 can apply for the Engineering/Physics/Mathematics Foundation Year
QCF BTEC
D*-D in the BTEC Subsidiary Diploma plus grades AA-A*A in A-level physics and A-level mathematics or further mathematics.
We will consider the BTEC Extended Diploma if it has been studied alongside A-levels in mathematics/further mathematics and physics.
We will consider the BTEC Diploma if it has been 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.
Access to HE Diploma
Not accepted for this course. Applicants with an Access to HE Diploma in a relevant subject should apply for the Engineering/Physics/Mathematics Foundation Year
Irish Leaving Certificate
Irish Leaving Certificate (first awarded 2017)
H1,H1,H1,H2,H2,H2- H1,H1,H2,H2,H2,H2 including mathematics, applied mathematics and physics
Irish certificate additional information
Successful applicants will be invited to visit the department and attend an optional interview. The optional interview may lead to a lower offer. Applicants who have not studied mathematics and/or physics can apply for the Engineering/Physics/Mathematics Foundation Year
Scottish Qualification
Offers will be based on exams being taken at the end of S6. Subjects taken and qualifications achieved in S5 will be reviewed. Careful consideration will be given to an individual’s academic achievement, taking in to account the context and circumstances of their pre-university education.
Please see the University of Southampton’s Curriculum for Excellence Scotland Statement (PDF) for further information. Applicants are advised to contact their Faculty Admissions Office for more information.
Cambridge Pre-U
D2 D3 D3 - D3 D3 D3 in three Principal subjects including physics (minimum grade D3) and either mathematics or further mathematics (minimum grade D3)
Cambridge Pre-U additional information
Cambridge Pre-U's can be used in combination with other qualifications such as A Levels to achieve the equivalent of the typical offer, where D3 can be used in lieu of A Level grade A or grade M2 can be used in lieu of A Level grade B.
Successful applicants will be invited to visit the department and attend an optional interview. The optional interview may lead to a lower offer.
Applicants who have not studied the required Principal subjects can apply for the Engineering/Physics/Mathematics Foundation Year
Welsh Baccalaureate
A*AA-AAA including physics (minimum grade A) and either mathematics or further mathematics (minimum grade A)
or
A*A-AA from two A-levels including physics and either mathematics or further mathematics and A from the Advanced Welsh Baccalaureate Skills Challenge Certificate
or
AAAB-AABB including physics (minimum grade A) and either mathematics or further mathematics (minimum grade A)
or
AA from two A-levels including physics and either mathematics or further mathematics, plus grades AB-BB from a third A-level and the Advanced Welsh Baccalaureate Skills Challenge Certificate
Welsh Baccalaureate additional information
Successful applicants will be invited to visit the department and attend an optional interview. The optional interview may lead to a lower offer.
A pass in the science Practical is required where it is separately endorsed.
Offers typically exclude General Studies and Critical Thinking.
Applicants who have not studied mathematics/further mathematics and/or physics at A-level can apply for the Engineering/Physics/Mathematics Foundation Year
Welsh Baccalaureate 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.
T-Level
Not accepted for this course. Applicants with a T level Technical Qualification in a relevant subject can apply for the Engineering/Physics/Mathematics Foundation Year
Other requirements
GCSE requirements
Applicants must hold GCSE English language (or GCSE English) (minimum grade 4/C) and mathematics (minimum grade 4/C)
Find the equivalent international qualifications for our entry requirements.
English language requirements
If English isn't your first language, you'll need to complete an International English Language Testing System (IELTS) to demonstrate your competence in English. You'll need all of the following scores as a minimum:
IELTS score requirements
- overall score
- 6.5
- reading
- 6.0
- writing
- 6.0
- speaking
- 6.0
- listening
- 6.0
We accept other English language tests. Find out which English language tests we accept.
If you don’t meet the English language requirements, you can achieve the level you need by completing a pre-sessional English programme before you start your course.
You might meet our criteria in other ways if you do not have the qualifications we need. Find out more about:
- our Ignite your Journey scheme for students living permanently in the UK (including residential summer school, application support and scholarship)
- skills you might have gained through work or other life experiences (otherwise known as recognition of prior learning)
Find out more about our Admissions Policy.
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.
You’ll study core physics subjects and space science modules.
Right from the start you’ll do mini-projects in the lab and apply your analytical and problem-solving skills.
Year 1 overview
This consists of core modules to give you a grounding in the key principles of physics and experimentation.
These include:
- physics skills
- mathematical methods
- waves and light
- energy and matter
- motion and relativity
- electricity and magnetism
There will also be an introduction to astronomy and space science.
Year 2 overview
Core modules include topics on:
- electromagnetism
- quantum physics
- classical mechanics
- practical photonics
You’ll also study the 'European dimension in space and astronautics' module.
Year 3 overview
Core modules in year 3 cover everything from particle physics to theories of matter, space and time and atomic physics.
There is also an individual dissertation and space science modules on space plasma physics and advanced astronautics.
Year 4 overview
In the fourth year you’ll work with another student on an extended research project on as aspects of space science that interests you.
You’ll have access to research data, for example, from the European Space Agency and NASA space missions, or our monitoring instrumentation in the Arctic.
Optional modules include study of:
- nanoscience
- applied nuclear physics
- cosmology and the early universe
- relativity
- black holes
- astrophysics
- advanced quantum physics
- particle physics
- spacecraft orbital mechanics and control
Want more detail? See all the modules in the course.
Modules
The modules outlined provide examples of what you can expect to learn on this degree course based on recent academic teaching. As a research-led University, we undertake a continuous review of our course to ensure quality enhancement and to manage our resources. The precise modules available to you in future years may vary depending on staff availability and research interests, new topics of study, timetabling and student demand. Find out why, when and how we might make changes.
For entry in academic year 2025 to 2026
Year 1 modules
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
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...
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 ...
Year 2 modules
You must study the following modules in year 2:
Astronautics
This module introduces the fundamental concepts of astronautics and spacecraft engineering and applies the design approach to case studies based on Earth observation missions.
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.
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...
European Dimension in Space
This module will provide students with an insight into the advantages of collaboration within Europe for the promotion of Space Science. The mechanism for the selection of missions and their subsequent development will be illustrated using a number of top...
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...
Year 3 modules
You must study the following modules in year 3:
Advanced Astronautics
Advanced Astronautics picks up where year 2 Astronautics left off. In this module you will further study Orbital Mechanics, while learning about relevant requirements, norms, standards and best practices. You will apply this knowledge to sustainable sp...
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...
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...
Dissertation
The first part of the course is devoted to exploring a given topic via group work, assessed via short, written summary (extended abstract) and oral presentation. The second part consists of an individual dissertation that is assessed via a written report...
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...
Physics from Evidence II
A wide variety of physics topics is covered, showing the experimental evidence underlying a number of topics in physics encountered in lecture courses and textbooks. Students are also introduced to techniques they might encounter in a physics-related care...
Space Plasma Physics
The aim of this course is to explore the physical processes which occur in the space environment. Theories of solar wind propagation and its interaction with the earth are developed and compared with data from satellites and ground based observatories. ...
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.
Year 4 modules
You must study the following modules in year 4:
MPhys Final Year Synoptic Examination
Students in the synoptic exam will be expected to display a broad knowledge and understanding of the core first, second and third year courses, to understand the inter-relations between those courses and to display problem solving skills in novel problem ...
MPhys Project
In this module, students undertake a research project which extends over both semesters of the final year. Students normally work in pairs, in close collaboration with a member of staff.
Spacecraft Orbital Mechanics
This module introduces students to the fundamental concepts of spaceflight orbital mechanics and then elaborates on trajectory design for planet centred and interplanetary missions. It covers the design and characterisation of planet-centred orbits in ...
You must also choose from the following modules in year 4:
Advanced Quantum Physics
This course will cover advanced topics of quantum mechanics including postulates of quantum mechanics, tools of quantum mechanics, Dirac notation, Simple Harmonic oscillator (studied using raising and lowering operators), orbital and spin angular momentum...
Applied Nuclear Physics
The aim of this course is to communicate knowledge of physical techniques which exploit nuclear particles, and to develop an understanding of the underlying physics. Important themes are nuclear processes and the interaction of nuclear radiation with the ...
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...
Lasers
Lasers and photonic techniques are used in all branches of science and technology. The principles of laser operation will be discussed, with reference to commonly used laser systems. The course provides knowledge of the laser as a fundamental tool of cont...
Nanoscience: technology and advanced materials
This course aims to provide you with an insight into some of the current research in nanoscience and an understanding of the underlying nanophysics. The field of nanoscience is multidisciplinary covering materials science, photonics, chemistry and biology...
Particle Physics
Relativistic wave equations with their predictions of anti-particles and fermion spin will be explored. The fundamental role of gauge symmetries in current theories of force will lead to the study of the standard model of particle physics, including the s...
Physics of the Early Universe
Since the end of the 1990s, cosmology has experienced one of the most impressive advances among all scientific disciplines. This happened mainly because of astonishing progress in the precision and accuracy of astronomical and cosmological observations ...
Physics of the Upper Atmosphere
The upper atmosphere consists of the outermost layers of Earth's atmosphere, above about 90 km altitude, on the edge of space. It is a very different place to the atmosphere we live in at ground level; temperatures reach extremes of cold (< 200 K) and ext...
Quantum Information
Quantum information combines information science with quantum effects in physics to study of how to process and transmit information using quantum systems. This includes quantum computation, quantum teleportation and quantum cryptography. Quantum metrol...
Quantum Optics
While coherence phenomena have long been familiar in the context of light waves, their manifestation in the context of matter waves is an exciting development of modern quantum science. This course aims to introduce the basic concepts needed to understand...
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)
Course time
How you'll spend your course time:
Year 1
Study time
Your scheduled learning, teaching and independent study for year 1:
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:
Year 2
Study time
Your scheduled learning, teaching and independent study for year 2:
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 2:
Academic support
You’ll be supported by a personal academic tutor and have access to a senior tutor.
Course leader
Robert Fear is the course leader.
Careers
Space science career jobs are in high demand. The global space economy is expanding, the government is planning to increase the UK’s share of the space market, and there’s a proliferation of new commercial space ventures.
In addition, the importance of monitoring space weather is increasingly recognised - severe space weather is now listed as one of the highest priority natural hazards in the UK National Risk Register.
The UK space sector has trebled in size in the last decade and the global space economy is set to double to £400 billion by 2030, so this is a dynamic and growing sector of the economy.
You’ll be able to apply your knowledge in a growing number of fields, including space-based scientific research, telecommunications and satellite imaging. Or you could choose to go on to further study at PhD level - a path followed by around a third of our physics and astronomy graduates.
A physics degree also opens up a huge range of other career options. Types of roles include:
- astrophysicist
- air traffic controller
- science policy officer
- medical physicist
- satellite engineer
- systems analyst
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.
Careers services at Southampton
We are a top 20 UK university for employability (QS Graduate Employability Rankings 2022). Our Careers, Employability and Student Enterprise team will support you. 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.
Work in industry
We can help you find a paid summer placement to give you valuable hands-on experience and the chance to make industry contacts.
Fees, costs and funding
Tuition fees
Fees for a year's study:
- UK students pay £9,250.
- EU and international students pay £29,400.
The Government has recently announced changes to UK tuition fees from September 2025 onwards. We will update our website to reflect this shortly.
What your fees pay for
Your tuition fees pay for the full cost of tuition and standard exams.
Find out how to:
Accommodation and living costs, such as travel and food, are not included in your tuition fees. There may also be extra costs for retake and professional exams.
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 to help fund your studies.
We award scholarships and grants for travel, academic excellence, or to students from under-represented backgrounds.
Support during your course
The Student Hub 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.
How to apply
What happens after you apply?
We will assess your application on the strength of your:
- predicted grades
- academic achievements
- personal statement
- academic reference
If you’re successful, we’ll invite you to an optional applicant visit day. This will give the opportunity to learn more about the department and take an interview, which may lead to a lower offer. If you attend a visit day before Christmas, you can take the physics academic scholarship exam.
We'll aim to process your application within 2 to 6 weeks, but this will depend on when it is submitted. Applications submitted in January, particularly near to the UCAS equal consideration deadline, might take substantially longer to be processed due to the high volume received at that time.
Equality and diversity
We treat and select everyone in line with our Equality and Diversity Statement.
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
Related courses
Physics with Space Science (MPhys) is a course in the Physics and astronomy subject area. Here are some other courses within this subject area:
-
Study
- View all courses
- Taught postgraduate study
- Pre-sessional English courses
-
Subjects
- Acoustical engineering
- Audiology
- Biomedical and medical engineering
- Civil engineering
- Every day I’m completely immersed in an environment that’s creative in all aspects
- Everything I learn feels so relevant, even If it’s a subject rooted in the past
- Maritime engineering
- Photonics and optoelectronics
- Social statistics and demography
-
PhDs and research degrees
- Create your own research project
-
Find a PhD project
- A missing link between continental shelves and the deep sea: Have we underestimated the importance of land-detached canyons?
- A study of rolling contact fatigue in electric vehicles (EVs)
- Acoustic monitoring of forest exploitation to establish community perspectives of sustainable hunting
- Acoustic sensing and characterisation of soil organic matter
- Advancing intersectional geographies of diaspora-led development in times of multiple crises
- Aero engine fan wake turbulence – Simulation and wind tunnel experiments
- Against Climate Change (DACC): improving the estimates of forest fire smoke emissions
- All-in-one Mars in-situ resource utilisation (ISRU) system and life-supporting using non-thermal plasma
- An electromagnetic study of the continent-ocean transition southwest of the UK
- An investigation of the relationship between health, home and law in the context of poor and precarious housing, and complex and advanced illness
- Antibiotic resistance genes in chalk streams
- Being autistic in care: Understanding differences in care experiences including breakdowns in placements for autistic and non-autistic children
- Biogeochemical cycling in the critical coastal zone: Developing novel methods to make reliable measurements of geochemical fluxes in permeable sediments
- Bloom and bust: seasonal cycles of phytoplankton and carbon flux
- British Black Lives Matter: The emergence of a modern civil rights movement
- Building physics for low carbon comfort using artificial intelligence
- Building-resolved large-eddy simulations of wind and dispersion over a city scale urban area
- Business studies and management: accounting
- Business studies and management: banking and finance
- Business studies and management: decision analytics and risk
- Business studies and management: digital and data driven marketing
- Business studies and management: human resources (HR) management and organisational behaviour
- Business studies and management: strategy, innovation and entrepreneurship
- Carbon storage in reactive rock systems: determining the coupling of geo-chemo-mechanical processes in reactive transport
- Cascading hazards from the largest volcanic eruption in over a century: What happened when Hunga Tonga-Hunga Ha’apai erupted in January 2022?
- Characterisation of cast austenitic stainless steels using ultrasonic backscatter and artificial intelligence
- Climate Change effects on the developmental physiology of the small-spotted catshark
- Climate at the time of the Human settlement of the Eastern Pacific
- Collaborative privacy in data marketplaces
- Compatibility of climate and biodiversity targets under future land use change
- Cost of living in modern and fossil animals
- Creative clusters in rural, coastal and post-industrial towns
- Deep oceanic convection: the outsized role of small-scale processes
- Defect categories and their realisation in supersymmetric gauge theory
- Defining the Marine Fisheries-Energy-Environment Nexus: Learning from shocks to enhance natural resource resilience
- Design and fabrication of next generation optical fibres
- Developing a practical application of unmanned aerial vehicle technologies for conservation research and monitoring of endangered wildlife
- Development and evolution of animal biomineral skeletons
- Development of all-in-one in-situ resource utilisation system for crewed Mars exploration missions
- Ecological role of offshore artificial structures
- Effect of embankment and subgrade weathering on railway track performance
- Efficient ‘whole-life’ anchoring systems for offshore floating renewables
- Electrochemical sensing of the sea surface microlayer
- Engagement with nature among children from minority ethnic backgrounds
- Enhancing UAV manoeuvres and control using distributed sensor arrays
- Ensuring the Safety and Security of Autonomous Cyber-Physical Systems
- Environmental and genetic determinants of Brassica crop damage by the agricultural pest Diamondback moth
- Estimating marine mammal abundance and distribution from passive acoustic and biotelemetry data
- Evolution of symbiosis in a warmer world
- Examining evolutionary loss of calcification in coccolithophores
- Explainable AI (XAI) for health
- Explaining process, pattern and dynamics of marine predator hotspots in the Southern Ocean
- Exploring dynamics of natural capital in coastal barrier systems
- Exploring the mechanisms of microplastics incorporation and their influence on the functioning of coral holobionts
- Exploring the potential electrical activity of gut for healthcare and wellbeing
- Exploring the trans-local nature of cultural scene
- Facilitating forest restoration sustainability of tropical swidden agriculture
- Faulting, fluids and geohazards within subduction zone forearcs
- Faulting, magmatism and fluid flow during volcanic rifting in East Africa
- Fingerprinting environmental releases from nuclear facilities
- Flexible hybrid thermoelectric materials for wearable energy harvesting
- Floating hydrokinetic power converter
- Glacial sedimentology associated subglacial hydrology
- Green and sustainable Internet of Things
- How do antimicrobial peptides alter T cell cytokine production?
- How do calcifying marine organisms grow? Determining the role of non-classical precipitation processes in biogenic marine calcite formation
- How do neutrophils alter T cell metabolism?
- How well can we predict future changes in biodiversity using machine learning?
- Hydrant dynamics for acoustic leak detection in water pipes
- If ‘Black Lives Matter’, do ‘Asian Lives Matter’ too? Impact trajectories of organisation activism on wellbeing of ethnic minority communities
- Illuminating luciferin bioluminescence in dinoflagellates
- Imaging quantum materials with an XFEL
- Impact of neuromodulating drugs on gut microbiome homeostasis
- Impact of pharmaceuticals in the marine environment in a changing world
- Improving subsea navigation using environment observations for long term autonomy
- Information theoretic methods for sensor management
- Installation effect on the noise of small high speed fans
- Integrated earth observation mapping change land sea
- Interconnections of past greenhouse climates
- Investigating IgG cell depletion mechanisms
- Is ocean mixing upside down? How mixing processes drive upwelling in a deep-ocean basin
- Landing gear aerodynamics and aeroacoustics
- Lightweight gas storage: real-world strategies for the hydrogen economy
- Machine learning for multi-robot perception
- Machine learning for multi-robot perception
- Marine ecosystem responses to past climate change and its oceanographic impacts
- Mechanical effects in the surf zone - in situ electrochemical sensing
- Microfluidic cell isolation systems for sepsis
- Migrant entrepreneurship, gender and generation: context and family dynamics in small town Britain
- Miniaturisation in fishes: evolutionary and ecological perspectives
- Modelling high-power fibre laser and amplifier stability
- Modelling soil dewatering and recharge for cost-effective and climate resilient infrastructure
- Modelling the evolution of adaptive responses to climate change across spatial landscapes
- Nanomaterials sensors for biomedicine and/or the environment
- New high-resolution observations of ocean surface current and winds from innovative airborne and satellite measurements
- New perspectives on ocean photosynthesis
- Novel methods of detecting carbon cycling pathways in lakes and their impact on ecosystem change
- Novel technologies for cyber-physical security
- Novel transparent conducting films with unusual optoelectronic properties
- Novel wavelength fibre lasers for industrial applications
- Ocean circulation and the Southern Ocean carbon sink
- Ocean influence on recent climate extremes
- Ocean methane sensing using novel surface plasmon resonance technology
- Ocean physics and ecology: can robots disentangle the mix?
- Ocean-based Carbon Dioxide Removal: Assessing the utility of coastal enhanced weathering
- Offshore renewable energy (ORE) foundations on rock seabeds: advancing design through analogue testing and modelling
- Optical fibre sensing for acoustic leak detection in buried pipelines
- Optimal energy transfer in nonlinear systems
- Optimal energy transfer in nonlinear systems
- Optimizing machine learning for embedded systems
- Oxidation of fossil organic matter as a source of atmospheric CO2
- Partnership dissolution and re-formation in later life among individuals from minority ethnic communities in the UK
- Personalized multimodal human-robot interactions
- Preventing disease by enhancing the cleaning power of domestic water taps using sound
- Quantifying riparian vegetation dynamics and flow interactions for Nature Based Solutions using novel environmental sensing techniques
- Quantifying the response and sensitivity of tropical forest carbon sinks to various drivers
- Quantifying variability in phytoplankton electron requirements for carbon fixation
- Resilient and sustainable steel-framed building structures
- Resolving Antarctic meltwater events in Southern Ocean marine sediments and exploring their significance using climate models
- Robust acoustic leak detection in water pipes using contact sound guides
- Silicon synapses for artificial intelligence hardware
- Smart photon delivery via reconfigurable optical fibres
- The Gulf Stream control of the North Atlantic carbon sink
- The Mayflower Studentship: a prestigious fully funded PhD studentship in bioscience
- The calming effect of group living in social fishes
- The duration of ridge flank hydrothermal exchange and its role in global biogeochemical cycles
- The evolution of symmetry in echinoderms
- The impact of early life stress on neuronal enhancer function
- The oceanic fingerprints on changing monsoons over South and Southeast Asia
- The role of iron in nitrogen fixation and photosynthesis in changing polar oceans
- The role of singlet oxygen signaling in plant responses to heat and drought stress
- Time variability on turbulent mixing of heat around melting ice in the West Antarctic
- Triggers and Feedbacks of Climate Tipping Points
- Uncovering the drivers of non-alcoholic fatty liver disease progression using patient derived organoids
- Understanding recent land-use change in Snowdonia to plan a sustainable future for uplands: integrating palaeoecology and conservation practice
- Understanding the role of cell motility in resource acquisition by marine phytoplankton
- Understanding the structure and engagement of personal networks that support older people with complex care needs in marginalised communities and their ability to adapt to increasingly ‘digitalised’ health and social care
- Unpicking the Anthropocene in the Hawaiian Archipelago
- Unraveling oceanic multi-element cycles using single cell ionomics
- Unravelling southwest Indian Ocean biological productivity and physics: a machine learning approach
- Using acoustics to monitor how small cracks develop into bursts in pipelines
- Using machine learning to improve predictions of ocean carbon storage by marine life
- Vulnerability of low-lying coastal transportation networks to natural hazards
- X-ray imaging and property characterisation of porous materials
- Funding your research degree
- How to apply for a PhD or research degree
- How to make a PhD enquiry
- Support while studying your PhD or research degree
- Exchanges and studying abroad
- Undergraduate study
-
Tuition fees and funding
-
Scholarships
-
Postgraduate scholarships for UK students
- Black Futures scholarship
- GREAT Scholarships 2025 – Egypt
- GREAT Scholarships 2025 – France
- GREAT Scholarships 2025 – Ghana
- Postgraduate Taught Diversity Scholarship (Environmental and Life Sciences)
- Southampton Business School Postgraduate UK Scholarship
- Southampton Genomics Talent Scholarship
- Southampton History Patricia Mather and Helen Patterson Scholarship
- Southampton MA Holocaust scholarships
- Southampton Philosophy David Humphris-Norman Scholarship
- Southampton Photonics Impact Scholarship
- Southampton UK Alumni Music Scholarship
- The National Institute for Health and care Research South Central INSIGHT Programme
- The South Coast Doctoral Training Partnership Social Science PhD Studentships
- Undergraduate scholarships for UK students
- Competitive scholarships for international postgraduates
- Competitive scholarships for international undergraduates
- Merit scholarships for international postgraduates
- Merit scholarships for international undergraduates
-
Partnership scholarships for international students
- Scholarships, awards and funding opportunities
- Becas Chile Scholarship
- Chevening Scholarships
- China Scholarship Council Scholarships
- COLFUTURO Scholarships
- Commonwealth Master's Scholarships
- Commonwealth PhD Scholarships
- Commonwealth PhD Scholarships for high income countries
- Commonwealth Shared Scholarships
- Commonwealth Split-Site Scholarships
- FIDERH Scholarships
- Fulbright Awards
- FUNED Scholarships
- Great Scholarships 2024 – Mexico
- Great Scholarships 2024 – Nigeria
- Marshall Scholarship
- Saïd Foundation Scholarships
- British Council Scholarships for Women in STEM
- Southampton Canadian Prestige Scholarship for Law
- Xiamen University PhD Scholarships
- Scholarship terms and conditions
-
Postgraduate scholarships for UK students
-
Scholarships
- Short courses
- Lunchtime evening and weekend courses
- Clearing
- Summer schools
- Get a prospectus
- Student life
-
Research
- Our impact
- Research projects
- Research areas
- Research facilities
- Collaborate with us
-
Institutes, centres and groups
- Active Living
- Advanced Fibre Applications
- Advanced Laser Laboratory
- Advanced Project Management Research Centre
- Antibody and Vaccine Group
- Astronomy Group
- Autism Community Research Network @ Southampton (ACoRNS)
- Bioarchaeology and Osteoarchaeology at Southampton (BOS)
- Bladder and Bowel Management
- Cell and Developmental Biology
- Centre for Defence and Security Research
- Centre for Developmental Origins of Health and Disease
- Centre for Digital Finance
- Centre for Eastern European and Eurasian Studies (CEEES)
- Centre for Empirical Research in Finance and Banking (CERFIB)
- Centre for Geometry, Topology, and Applications
- Centre for Global Englishes
- Centre for Global Health and Policy (GHaP)
- Centre for Green Maritime Innovation (cGMI)
- Centre for Health Technologies
- Centre for Healthcare Analytics
- Centre for Human Development, Stem Cells and Regeneration
- Centre for Imperial and Postcolonial Studies
- Centre for Inclusive and Sustainable Entrepreneurship and Innovation (CISEI)
- Centre for International Film Research (CIFR)
- Centre for International Law and Globalisation
- Centre for Internet of Things and Pervasive Systems
- Centre for Justice Studies
- Centre for Linguistics, Language Education and Acquisition Research
- Centre for Machine Intelligence
- Centre for Maritime Archaeology
- Centre for Medieval and Renaissance Culture (CMRC)
- Centre for Modern and Contemporary Writing (CMCW)
- Centre for Political Ethnography (CPE)
- Centre for Research in Accounting, Accountability and Governance
- Centre for Research on Work and Organisations
- Centre for Resilient Socio-Technical Systems
- Centre for Transnational Studies
- Child and Adolescent Research Group
- Clinical Ethics, Law and Society (CELS)
- Computational Nonlinear Optics
- Cyber Security Academy
- Data Science Group
- Digital Oceans
- EPSRC and MOD Centre for Doctoral Training in Complex Integrated Systems for Defence and Security
- Economic Theory and Experimental Economics
- Economy, Society and Governance
- Electrical Power Engineering
- Environmental Hydraulics
- Gas Photonics in Hollow Core Fibres
- Geochemistry
- Global Health (Demography)
- Global Health Community of Practice
- Gravity group
- Healthy Oceans
- High Power Fibre Lasers
- Hollow Core Fibre
- Human Genetics and Genomic Medicine
- Infection
- Infrastructure Group
- Institute of Developmental Sciences
- Institute of Maritime Law (IML)
- Integrated Photonic Devices
- Integrative Molecular Phenotyping Centre
- Interdisciplinary Musculoskeletal Health
- International Centre for Ecohydraulics Research (ICER)
- Language Assessment and Testing Unit (LATU)
- Laser-Direct-Write (LDW) Technologies for Biomedical Applications
- Law and Technology Centre
- Long Term Conditions
- Magnetic Resonance
- Mathematical Modelling
- Medicines Management
- Molecular and Precision Biosciences
- Multiwavelength Accretion and Astronomical Transients
- National Biofilms Innovation Centre (NBIC)
- National Centre for Research Methods
- National Infrastructure Laboratory
- Nature-Based Ocean Solutions
- Nonlinear Semiconductor Photonics
- Ocean Perception Group
- Operational Research
- Optical Engineering and Quantum Photonics Group
- Paediatrics and Child Health - Clinical and Experimental Sciences
- People, Property, Community
- Photonic Systems, Circuits and Sensors Group
- Physical Optics
- Primary Care Research Centre
- Quantum, Light and Matter Group
- Silica Fibre Fabrication
- Silicon Photonics
- Skin Sensing Research Group
- Southampton Centre for Nineteenth-Century Research
- Southampton Ethics Centre
- Southampton Health Technology Assessments Centre (SHTAC)
- Southampton High Energy Physics group
- Southampton Imaging
- Southampton Theory Astrophysics and Gravity (STAG) Research Centre
- Stefan Cross Centre for Women, Equality and Law
- String theory and holography
- The India Centre for Inclusive Growth and Sustainable Development
- The Parkes Institute
- Tony Davies High Voltage Laboratory
- Ultrafast X-ray Group
- Vision Science
- WSA Exchange
- Work Futures Research Centre (WFRC)
- Support for researchers
- Faculties, schools and departments
- Research jobs
- Find people and expertise
- Business
- Global
- About
- Visit
- Alumni
- Departments
- News
- Events
- Contact