Programme Information | University of Exeter

1. Programme Title: Physics with Astrophysics	NQF Level:	7

2. Description of the Programme (as in the Business Approval Form)
This physics programme will give you an excellent understanding of mainstream physics and develop your scientific intuition and prepare you for a wide range of careers. Our physics programmes are designed around a core curriculum, which can lead naturally on to PhD-level research or towards a more specialised qualification such as an MSc, and all are accredited by the Institute of Physics. In Stage 1 you will develop your understanding of physics and become familiar with a variety of basic mathematical tools. The concepts and phenomena you will meet are many and varied, but are united by the underlying principles of physics. In a typical week you will spend 15 hours in a formal teaching environment, and be expected to spend a further 20 hours in independent study. You will have four hours of lectures in physics, two in mathematics, one tutorial, six hours in the teaching laboratories and two hours in problem-solving classes. Stage 2 provides a firm foundation of physics, and the principles that constitute the framework of the subject. The use of mathematics gives these principles a precise form and provides physicists with the ability to make detailed quantitative predictions. This year focuses on four main cornerstones of physics: condensed matter, quantum mechanics, electromagnetism and thermodynamics. These provide the core of most of physics and of our understanding of the evolution of our universe. The other modules in your second and subsequent years draw in part on your knowledge of this core. There is a 0-credit Employability and Placement Preparation module that all Stage 2 students can take. This will benefit those who are considering doing a work placement/year in industry as part of their degree programme and is highly recommended for those who are already on the “with Professional Placement” element of their degree programme. There will be support sessions and workshops by Careers Consultants and speakers from industry that will prepare students for the recruitment cycle and applying for placements. Stage 3 develops your problem-solving and knowledge of core physics in key areas, such as nuclear and high-energy particle physics and electrodynamics. You will also apply this knowledge to more specialised areas covered by astrophysics modules. Stage 3 of this MPhys Physics programme also involves substantial project work on a topic related to one of the Department's astrophysics research area. You will work in a small group (typically three or four, but with individual roles), to undertake a project that will continue to completion at the end of your final year. The projects are original and open-ended, i.e., they each focus on a previously unstudied area or problem. You will meet with your supervisor (a professor or lecturer) once a week to discuss progress and future work. In Stage 4, about half your time will be spent on masters-level core and optional physics modules with work on your research project, continuing from Stage 3, filling the remainder. You will also be encouraged to attend research seminars from visiting speakers, attend the weekly group meetings held by the Department's research groups, and engage with the PhD students and researchers who work here.

2. Description of the Programme (as in the Business Approval Form)

This physics programme will give you an excellent understanding of mainstream physics and develop your scientific intuition and prepare you for a wide range of careers. Our physics programmes are designed around a core curriculum, which can lead naturally on to PhD-level research or towards a more specialised qualification such as an MSc, and all are accredited by the Institute of Physics.

In Stage 1 you will develop your understanding of physics and become familiar with a variety of basic mathematical tools. The concepts and phenomena you will meet are many and varied, but are united by the underlying principles of physics. In a typical week you will spend 15 hours in a formal teaching environment, and be expected to spend a further 20 hours in independent study. You will have four hours of lectures in physics, two in mathematics, one tutorial, six hours in the teaching laboratories and two hours in problem-solving classes.

Stage 2 provides a firm foundation of physics, and the principles that constitute the framework of the subject. The use of mathematics gives these principles a precise form and provides physicists with the ability to make detailed quantitative predictions. This year focuses on four main cornerstones of physics: condensed matter, quantum mechanics, electromagnetism and thermodynamics. These provide the core of most of physics and of our understanding of the evolution of our universe. The other modules in your second and subsequent years draw in part on your knowledge of this core. There is a 0-credit Employability and Placement Preparation module that all Stage 2 students can take. This will benefit those who are considering doing a work placement/year in industry as part of their degree programme and is highly recommended for those who are already on the “with Professional Placement” element of their degree programme. There will be support sessions and workshops by Careers Consultants and speakers from industry that will prepare students for the recruitment cycle and applying for placements.

Stage 3 develops your problem-solving and knowledge of core physics in key areas, such as nuclear and high-energy particle physics and electrodynamics. You will also apply this knowledge to more specialised areas covered by astrophysics modules.

Stage 3 of this MPhys Physics programme also involves substantial project work on a topic related to one of the Department's astrophysics research area. You will work in a small group (typically three or four, but with individual roles), to undertake a project that will continue to completion at the end of your final year. The projects are original and open-ended, i.e., they each focus on a previously unstudied area or problem. You will meet with your supervisor (a professor or lecturer) once a week to discuss progress and future work.

In Stage 4, about half your time will be spent on masters-level core and optional physics modules with work on your research project, continuing from Stage 3, filling the remainder. You will also be encouraged to attend research seminars from visiting speakers, attend the weekly group meetings held by the Department's research groups, and engage with the PhD students and researchers who work here.

3. Educational Aims of the Programme
This programme is intended to: Provide education and training of high quality in physics. Stimulate and encourage in students a questioning and creative approach, thus developing their enthusiasm for physics and a capacity for independent judgement. Facilitate students' personal development through the acquisition and use of a wide range of transferable skills. Provide students with a sound foundation in Physics with an emphasis on astrophysics, preparing them well for employment or further study and meeting the national needs for qualified graduates as identified by the relevant professional accrediting bodies. Produce graduate physicists who are well-prepared for more-advanced professional work, and research, in physics and related areas. Physics and Astronomy intends to provide students taking this programme with: Opportunities to engage with a range of advanced concepts and applications, drawing upon the specialist expertise of the staff. The opportunity, through the flexibility provided by a wide range of choices of both degree programmes and modules, to complete a programme of study relevant to their interests and aptitudes. Regular and frequent small-group contact with staff with the appropriate teaching skills and experience, including current activity in high-level research. An environment which is caring and supportive in both academic and pastoral aspects and which will have encompassed an appropriate range of teaching methods and broadened their learning experience.

3. Educational Aims of the Programme

This programme is intended to:

Provide education and training of high quality in physics.
Stimulate and encourage in students a questioning and creative approach, thus developing their enthusiasm for physics and a capacity for independent judgement.
Facilitate students' personal development through the acquisition and use of a wide range of transferable skills.
Provide students with a sound foundation in Physics with an emphasis on astrophysics, preparing them well for employment or further study and meeting the national needs for qualified graduates as identified by the relevant professional accrediting bodies.
Produce graduate physicists who are well-prepared for more-advanced professional work, and research, in physics and related areas.

Physics and Astronomy intends to provide students taking this programme with:

Opportunities to engage with a range of advanced concepts and applications, drawing upon the specialist expertise of the staff.
The opportunity, through the flexibility provided by a wide range of choices of both degree programmes and modules, to complete a programme of study relevant to their interests and aptitudes.
Regular and frequent small-group contact with staff with the appropriate teaching skills and experience, including current activity in high-level research.
An environment which is caring and supportive in both academic and pastoral aspects and which will have encompassed an appropriate range of teaching methods and broadened their learning experience.

4. Programme Structure
The programme is divided into units of study called modules. The credit rating of a module is proportional to the total workload. One credit is nominally equivalent to 10 hours of work. The level of a module indicates its position in the progressive development of academic cognitive abilities, and/or practical skills. An elective is an unspecified module that allows the student to broaden their education, e.g. by learning a foreign language. More details are given in the published module descriptors.

4. Programme Structure

The programme is divided into units of study called modules. The credit rating of a module is proportional to the total workload. One credit is nominally equivalent to 10 hours of work. The level of a module indicates its position in the progressive development of academic cognitive abilities, and/or practical skills. An elective is an unspecified module that allows the student to broaden their education, e.g. by learning a foreign language. More details are given in the published module descriptors.

5. Programme Modules

Stage 1

Code	Title	Credits	Compulsory	NonCondonable
PHY1021	Vector Mechanics	15	Yes	Yes
PHY1022	Introduction to Astrophysics	15	Yes	Yes
PHY1025	Mathematics Skills	15	Yes	Yes
PHY1027	Practical Physics I	15	Yes	Yes
PHY1023	Waves and Optics	15	Yes	Yes
PHY1024	Properties of Matter	15	Yes	Yes
PHY1026	Mathematics for Physicists	15	Yes	Yes
PHY1031	Scientific Programming in Python	15	No	No

Stage 2

Code	Title	Credits	Compulsory	NonCondonable
PHY2021	Electromagnetism I	15	Yes	Yes
PHY2022	Quantum Mechanics I	15	Yes	Yes
PHY2025	Mathematics with Physical Applications	15	Yes	Yes
PHY2026	Practical Physics II	15	Yes	Yes
PHY2023	Thermal Physics	15	Yes	Yes
PHY2024	Condensed Matter I	15	Yes	Yes
PHY2030	Observing the Universe	15	Yes	Yes
Choose 15 credits from List A:
PHY2027	Scientific Programming in C	15	No	No
PHY2222	Physics of Climate Change	15	No	No
Additional 0-credit optional module
PHY2038	Employability and Placement Preparation	0	No	No

Please note that 0-credit module PHY2038 Employability and Placement Preparation is entirely optional and can be taken in addition to a weighted module. It is recommended to those Stage 2 students who are considering or are on the ’with Professional Placement’ element of their degree programme.

Stage 3

Code	Title	Credits	Compulsory	NonCondonable
PHY3051	Electromagnetism II	15	Yes	No
PHY3070	Stars from Birth to Death	15	Yes	No
PHYM002	Quantum Mechanics II	15	Yes	No
PHY3053	General Problems	15	Yes	No
PHY3122	Project and Dissertation	30	Yes	Yes
PHY3052	Nuclear and High Energy Physics	15	Yes	No
PHY3066	Galaxies and High Energy Astrophysics	15	Yes	No

Stage 4

Code	Title	Credits	Compulsory	NonCondonable
PHYM001	Statistical Physics	15	Yes	No
PHYM012	Solar and Extra-Solar Planets and Their Atmospheres	15	Yes	No
PHYM009	Project and Dissertation	45	Yes	Yes
PHYM006	Relativity and Cosmology	15	Yes	No
PHYM003	Condensed Matter II	15	Yes	No
Choose 15 credits from List A:
PHYM004	Computational Physics and Modelling	15	No	No
PHYM013	Quantum Many-Body Theory	15	No	No
PHYM005	Independent Study	15	No	No
PHYM008	Physical Methods in Biology and Medicine	15	No	No
PHYM015	Quantum Optics and Photonics	15	No	No
Choose 15 credits from List B:
PHY3061	The Biophysics of Cells and Tissues	15	No	No
PHY3062	Methods of Theoretical Physics	15	No	No
PHY3064	Nanostructures and Graphene Science	15	No	No
PHY3067	Energy and the Environment	15	No	No
PHY3068	Principles of Theoretical Physics	15	No	No
PHY3071	Soft Matter	15	No	No
PHY3220	Fluid Dynamics in Physics and Astronomy	15	No	No

6. Programme Outcomes Linked to Teaching, Learning & Assessment Methods
On successfully completing the programme you will be able to:	Intended Learning Outcomes (ILOs) will be accommodated & facilitated by the following learning & teaching and evidenced by the following assessment methods:
A Specialised Subject Skills & Knowledge Demonstrate knowledge and understanding of most fundamental laws and principles of physics, along with their application to a variety of areas in physics, in particular their application in the contexts of astronomy and astrophysics, some of which are at (or are informed by) the forefront of the discipline. Solve advanced problems in physics using appropriate mathematical tools. Students should be able to identify the relevant physical principles, to translate problems into mathematical statements and apply their knowledge to obtain order-of-magnitude or more precise solutions as appropriate. Use mathematical techniques and analysis to model physical behaviour and interpret mathematical descriptions of physical phenomena.	Learning & Teaching Activities Material is introduced by lectures and directed reading/research. Students are given clear guidance in how to manage their learning and are expected to take progressively more responsibility for their own learning at each stage. Understanding is developed and consolidated in problems classes and tutorials and by laboratory work and private study exercises, carried out individually and in pairs or groups. A mix of self-assessed and tutor-marked work provides rapid feedback. Project work is used to integrate material and make knowledge functional. A set of compulsory core modules cover the 'fundamental physical laws' in progressively greater depth at each stage of the programme. These laws are applied in the options modules and projects at Stages 2-4. Mathematical skills are learned within dedicated modules and are applied and reinforced in the other Physics modules.
Assessment Methods Direct assessment is through a range of mid-semester tests (Stage 1 and 2 only), formal written examinations, and marked coursework in the form of problem sheets, laboratory reports, reports/essays based on directed reading and research. The MPhys project assessment is based on performance in project work, oral presentations, planning ability, a formal written report and a poster presentation. An important element is the ability of the student to defend their work during vivas. Students must answer questions not just from their immediate supervisor/lab-demonstrator, but also from a professional physicist with a different background and perspective. Assessment criteria are published in the Physics Handbook.
B Academic Discipline Core Skills & Knowledge Plan and execute under supervision, an experiment or investigation, analyse critically the results and draw valid conclusions. Students should be able to evaluate the level of uncertainty in their results, understand the significance of error analysis and be able to compare these results with expected outcomes, theoretical predictions or with published data. They should be able to evaluate the significance of their results in this context. Make effective use of IT skills at the level needed for project work; for example a familiarity with a programming language, simulation software, or the use of mathematical packages for manipulation and numerical solution of equations. Demonstrate a sound familiarity with laboratory apparatus and techniques.	Learning & Teaching Activities The Practical Physics modules at Stages 1 and 2 provide a thorough training in the execution and critical analysis of an experimental investigation. These skills are developed further in the final projects, which require students to plan and execute experiments. Students must also present and defend their conclusions. The 'IT Skills for Physicists' module, which is continually updated to reflect developments in technology, provides the essential training in IT skills needed by students to complete the programme. Other modules require students to apply and develop these skills. Several optional modules offer specific training in computer programming and packages. Computing and IT modules are taught in purpose-built computer rooms using a mix of lectures, and self-study packs supported by module instructors and demonstrators.
Assessment Methods Analytical skills are assessed within many modules through a range of formal written examinations, and marked coursework in the form of problem sheets, etc. These skills are primarily demonstrated in project work however. The MPhys project assessment is based on performance in project work, oral presentations, planning ability, a formal written report and a poster presentation. Assessment criteria are published in the Physics Handbook. IT skills are assessed directly with marked worksheets, assessed portfolios, and practical tests. They are also indirectly assessed because such skills are necessary to complete project work satisfactorily.
C Personal / Transferable / Employment Skills & Knowledge Demonstrate a working knowledge of a variety of experimental, mathematical and/or computational techniques applicable to current research within physics. Communicate complex scientific ideas, the conclusions of an experiment, investigation or project concisely, accurately and informatively. Manage your own learning and to make use of appropriate texts, research articles and other primary sources.	Learning & Teaching Activities Initial training in the manipulation, presentation and interpretation of data occurs during Stage 1 in the Mathematics, IT Skills, and Practical Physics modules and in tutorials. These skills are developed and used at progressively higher levels throughout the programme. Initial training in scientific communication occurs during Stage 1 in the Practical Physics module and in tutorials. These skills are developed and used at progressively higher levels throughout the programme. Students learn, with the guidance of tutors and module instructors, to take progressively more responsibility for managing their own learning at each stage of the programme. Students learn, via project work, to interact with research staff beyond their peer group. They learn to obtain help and insights from staff beyond the teaching faculty, an important skill when moving to more advanced research environments.
Assessment Methods Assessment of key skills is mostly through items of coursework: written and oral presentations, and through project work.

6. Programme Outcomes Linked to Teaching, Learning & Assessment Methods

On successfully completing the programme you will be able to:

Intended Learning Outcomes (ILOs) will be accommodated & facilitated by the following learning & teaching and evidenced by the following assessment methods:

A Specialised Subject Skills & Knowledge

Demonstrate knowledge and understanding of most fundamental laws and principles of physics, along with their application to a variety of areas in physics, in particular their application in the contexts of astronomy and astrophysics, some of which are at (or are informed by) the forefront of the discipline.
Solve advanced problems in physics using appropriate mathematical tools. Students should be able to identify the relevant physical principles, to translate problems into mathematical statements and apply their knowledge to obtain order-of-magnitude or more precise solutions as appropriate.
Use mathematical techniques and analysis to model physical behaviour and interpret mathematical descriptions of physical phenomena.

Learning & Teaching Activities

Material is introduced by lectures and directed reading/research. Students are given clear guidance in how to manage their learning and are expected to take progressively more responsibility for their own learning at each stage. Understanding is developed and consolidated in problems classes and tutorials and by laboratory work and private study exercises, carried out individually and in pairs or groups. A mix of self-assessed and tutor-marked work provides rapid feedback. Project work is used to integrate material and make knowledge functional. A set of compulsory core modules cover the 'fundamental physical laws' in progressively greater depth at each stage of the programme. These laws are applied in the options modules and projects at Stages 2-4. Mathematical skills are learned within dedicated modules and are applied and reinforced in the other Physics modules.

Assessment Methods

Direct assessment is through a range of mid-semester tests (Stage 1 and 2 only), formal written examinations, and marked coursework in the form of problem sheets, laboratory reports, reports/essays based on directed reading and research.
The MPhys project assessment is based on performance in project work, oral presentations, planning ability, a formal written report and a poster presentation. An important element is the ability of the student to defend their work during vivas. Students must answer questions not just from their immediate supervisor/lab-demonstrator, but also from a professional physicist with a different background and perspective. Assessment criteria are published in the Physics Handbook.

B Academic Discipline Core Skills & Knowledge

Plan and execute under supervision, an experiment or investigation, analyse critically the results and draw valid conclusions. Students should be able to evaluate the level of uncertainty in their results, understand the significance of error analysis and be able to compare these results with expected outcomes, theoretical predictions or with published data. They should be able to evaluate the significance of their results in this context.
Make effective use of IT skills at the level needed for project work; for example a familiarity with a programming language, simulation software, or the use of mathematical packages for manipulation and numerical solution of equations.
Demonstrate a sound familiarity with laboratory apparatus and techniques.

Learning & Teaching Activities

The Practical Physics modules at Stages 1 and 2 provide a thorough training in the execution and critical analysis of an experimental investigation. These skills are developed further in the final projects, which require students to plan and execute experiments. Students must also present and defend their conclusions.
The 'IT Skills for Physicists' module, which is continually updated to reflect developments in technology, provides the essential training in IT skills needed by students to complete the programme. Other modules require students to apply and develop these skills. Several optional modules offer specific training in computer programming and packages. Computing and IT modules are taught in purpose-built computer rooms using a mix of lectures, and self-study packs supported by module instructors and demonstrators.

Assessment Methods

Analytical skills are assessed within many modules through a range of formal written examinations, and marked coursework in the form of problem sheets, etc. These skills are primarily demonstrated in project work however. The MPhys project assessment is based on performance in project work, oral presentations, planning ability, a formal written report and a poster presentation. Assessment criteria are published in the Physics Handbook.
IT skills are assessed directly with marked worksheets, assessed portfolios, and practical tests. They are also indirectly assessed because such skills are necessary to complete project work satisfactorily.

C Personal / Transferable / Employment Skills & Knowledge

Demonstrate a working knowledge of a variety of experimental, mathematical and/or computational techniques applicable to current research within physics.
Communicate complex scientific ideas, the conclusions of an experiment, investigation or project concisely, accurately and informatively.
Manage your own learning and to make use of appropriate texts, research articles and other primary sources.

Learning & Teaching Activities

Initial training in the manipulation, presentation and interpretation of data occurs during Stage 1 in the Mathematics, IT Skills, and Practical Physics modules and in tutorials. These skills are developed and used at progressively higher levels throughout the programme.
Initial training in scientific communication occurs during Stage 1 in the Practical Physics module and in tutorials. These skills are developed and used at progressively higher levels throughout the programme.
Students learn, with the guidance of tutors and module instructors, to take progressively more responsibility for managing their own learning at each stage of the programme.
Students learn, via project work, to interact with research staff beyond their peer group. They learn to obtain help and insights from staff beyond the teaching faculty, an important skill when moving to more advanced research environments.

Assessment Methods

Assessment of key skills is mostly through items of coursework: written and oral presentations, and through project work.

7. Programme Regulations
7.1. Credit This MPhys programme consists of 480 credits with 120 credits taken at each stage. Normally not more than 75 credits would be allowed in any one term. In total, participants normally take no more than 120 credits at NQF level 4, and must take at least 210 credits at NQF levels 6 and 7, of which 120 must be at NQF level 7. The pass mark for award of credit is 40% for undergraduate modules (NQF levels 4–6) and 50% for masters-level modules (NQF level 7). 7.2. Progression Up to 30 credits of failure can be condoned in a stage of this MPhys Programme on the following conditions: You must have registered for and participated in modules amounting to at least 120 credits in the stage. You must pass the modules marked as 'non-condonable' in the tables above. In stage 1 you must achieve an average mark of at least 40.00% across the full 120 credits of assessment, including any failed and condoned modules. In stage 2 you must achieve an average mark of at least 59.50% across the full 120 credits of assessment, before referral and including any failed and condoned modules. In stage 3 you must achieve an average mark of at least 40.00% across the full 120 credits of assessment, including any failed and condoned modules. In the final stage you must achieve an average mark of at least 50.00% across the full 120 credits of assessment, including any failed and condoned modules. 7.3. Assessment and Awards Assessment at stage 1 does not contribute to the summative classification of the award. The award will normally be based on the degree mark formed from the credit-weighted average marks for stages 2, 3 and 4 combined in the ratio 2:3:4 respectively. 7.4. Classification The marking of modules and the classification of awards broadly corresponds to the following marks: Undergraduate Programmes Class I 70%+ Class II Division I 60–69% Class II Division II 50–59% Class III 40–49% Full details of assessment regulations for UG programmes and PGT programmes can be found on the University of Exeter website: Assessment, Progression and Awarding: Taught Programmes Handbook Generic marking criteria are also published here: Generic University Assessment Criteria for Taught Programmes Please see the Teaching and Quality Assurance Manual for further guidance. Teaching quality assurance manual (TQA Manual) 7.5. Interim Exit Awards A student who progresses to the final stage of this programme but does not then pass their Project and Dissertation module will be eligible for a BSc (Hons) Physical Science award. A final stage student who passes their Project and Dissertation module but fails more than 30 credits of other modules will be eligible for a BSc (Hons) Physics with Astrophysics award.

7. Programme Regulations

7.1. Credit

This MPhys programme consists of 480 credits with 120 credits taken at each stage. Normally not more than 75 credits would be allowed in any one term. In total, participants normally take no more than 120 credits at NQF level 4, and must take at least 210 credits at NQF levels 6 and 7, of which 120 must be at NQF level 7. The pass mark for award of credit is 40% for undergraduate modules (NQF levels 4–6) and 50% for masters-level modules (NQF level 7).

7.2. Progression

Up to 30 credits of failure can be condoned in a stage of this MPhys Programme on the following conditions:

You must have registered for and participated in modules amounting to at least 120 credits in the stage.
You must pass the modules marked as 'non-condonable' in the tables above.
In stage 1 you must achieve an average mark of at least 40.00% across the full 120 credits of assessment, including any failed and condoned modules.
In stage 2 you must achieve an average mark of at least 59.50% across the full 120 credits of assessment, before referral and including any failed and condoned modules.
In stage 3 you must achieve an average mark of at least 40.00% across the full 120 credits of assessment, including any failed and condoned modules.
In the final stage you must achieve an average mark of at least 50.00% across the full 120 credits of assessment, including any failed and condoned modules.

7.3. Assessment and Awards

Assessment at stage 1 does not contribute to the summative classification of the award. The award will normally be based on the degree mark formed from the credit-weighted average marks for stages 2, 3 and 4 combined in the ratio 2:3:4 respectively.

7.4. Classification

The marking of modules and the classification of awards broadly corresponds to the following marks:

Undergraduate Programmes

Class I 70%+

Class II Division I 60–69%

Class II Division II 50–59%

Class III 40–49%

Full details of assessment regulations for UG programmes and PGT programmes can be found on the University of Exeter website:

Assessment, Progression and Awarding: Taught Programmes Handbook

Generic marking criteria are also published here:

Generic University Assessment Criteria for Taught Programmes

Please see the Teaching and Quality Assurance Manual for further guidance.

Teaching quality assurance manual (TQA Manual)

7.5. Interim Exit Awards

A student who progresses to the final stage of this programme but does not then pass their Project and Dissertation module will be eligible for a BSc (Hons) Physical Science award. A final stage student who passes their Project and Dissertation module but fails more than 30 credits of other modules will be eligible for a BSc (Hons) Physics with Astrophysics award.

8. College Support for Students and Students' Learning
8.1. Infrastructure and Learning Environment Comprehensive details of this programme, support for its students and the learning environment are published in the Physics Handbook: Physics and Astronomy Handbook - Table of Contents Physical facilities include: well-equipped teaching and research laboratories, a mechanical student-workshop supervised by technicians, computer workstations and classrooms, social and quiet-working space for students. 8.2. Personal and Academic Tutoring It is University policy that all Colleges should have in place a system of academic and personal tutors. The role of academic tutors is to support you on individual modules; the role of personal tutors is to provide you with advice and support for the duration of the programme and extends to providing you with details of how to obtain support and guidance on personal difficulties such as accommodation, financial difficulties and sickness. You can also make an appointment to see individual teaching staff. Students on this programme are assigned a physics tutor, who combines the academic and personal roles and holds small-group (typically five students) tutorial meetings lasting an hour each week during the teaching periods. Further details of this system are published in the Physics Handbook: Undergraduate Physics Tutorials Each programme stage is supported and overseen by a stage coordinator (senior tutor) responsible for monitoring all aspects of the student experience: Programme Support Roles 8.3. Library and Other Learning Resources In addition to a large number of journals and academic works, the nearby University stocks reference and/or for-loan copies of all recommended texts for Physics modules. Where possible e-Books and e-Journal subscriptions are purchased to allow internet access. Each module has its own page on ELE, the Exeter virtual learning environment. Resources available for each module normally include sets of lecture slides/notes, video capture recordings of lectures, problems sets and examples, resources for self-study, etc. 8.4. Local Access to Computers and Printers There are approximately 100 computer workstations reserved for undergraduate use within the Physics Building. Facilities include two computer classrooms, printers and further provision within practical laboratories. Further details are published in the Physics Handbook: Information Technology Facilities 8.5. Student-Staff Liaison Committee The Student-Staff Liaison Committee (SSLC) enables students and staff to participate jointly in the management and review of the teaching and learning provision.

8. College Support for Students and Students' Learning

8.1. Infrastructure and Learning Environment

Comprehensive details of this programme, support for its students and the learning environment are published in the Physics Handbook:

Physics and Astronomy Handbook - Table of Contents

Physical facilities include: well-equipped teaching and research laboratories, a mechanical student-workshop supervised by technicians, computer workstations and classrooms, social and quiet-working space for students.

8.2. Personal and Academic Tutoring

It is University policy that all Colleges should have in place a system of academic and personal tutors. The role of academic tutors is to support you on individual modules; the role of personal tutors is to provide you with advice and support for the duration of the programme and extends to providing you with details of how to obtain support and guidance on personal difficulties such as accommodation, financial difficulties and sickness. You can also make an appointment to see individual teaching staff.

Students on this programme are assigned a physics tutor, who combines the academic and personal roles and holds small-group (typically five students) tutorial meetings lasting an hour each week during the teaching periods. Further details of this system are published in the Physics Handbook:

Undergraduate Physics Tutorials

Each programme stage is supported and overseen by a stage coordinator (senior tutor) responsible for monitoring all aspects of the student experience:

Programme Support Roles

8.3. Library and Other Learning Resources

In addition to a large number of journals and academic works, the nearby University stocks reference and/or for-loan copies of all recommended texts for Physics modules. Where possible e-Books and e-Journal subscriptions are purchased to allow internet access.

Each module has its own page on ELE, the Exeter virtual learning environment. Resources available for each module normally include sets of lecture slides/notes, video capture recordings of lectures, problems sets and examples, resources for self-study, etc.

8.4. Local Access to Computers and Printers

There are approximately 100 computer workstations reserved for undergraduate use within the Physics Building. Facilities include two computer classrooms, printers and further provision within practical laboratories. Further details are published in the Physics Handbook:

Information Technology Facilities

8.5. Student-Staff Liaison Committee

The Student-Staff Liaison Committee (SSLC) enables students and staff to participate jointly in the management and review of the teaching and learning provision.

10. Admission Criteria
All applications are considered individually on merit. The University is committed to an equal opportunities policy with respect to gender, age, race, sexual orientation and/or disability when dealing with applications. It is also committed to widening access to higher education to students from a diverse range of backgrounds and experience. Candidates must satisfy the: General admissions requirements of the University of Exeter. 10.1. Minimum Requirements The equivalent of at least: one grade A and one grade B in GCE AL Maths and Physics, or at least one HL6 and one HL5 in IB Mathematics and Physics are required for all Physics programmes. Applicants with other qualifications (for example the Access to Higher Education Diploma or Open University credits) may need to pass an AL-style mathematics test to demonstrate ability. This test will be undertaken as part of an interview. Applicants who meet our entry criteria will be invited to visit the Department between November and March. Places are not normally offered to applicants who do not participate in an interview. 10.2. Further Details Further details, including typical offers and English language requirements for International students are published on the University's Admissions webpages: Undergraduate Study > Subjects > Physics and Astronomy

10. Admission Criteria

All applications are considered individually on merit. The University is committed to an equal opportunities policy with respect to gender, age, race, sexual orientation and/or disability when dealing with applications. It is also committed to widening access to higher education to students from a diverse range of backgrounds and experience.

Candidates must satisfy the:

General admissions requirements of the University of Exeter.

10.1. Minimum Requirements

The equivalent of at least:

one grade A and one grade B in GCE AL Maths and Physics, or
at least one HL6 and one HL5 in IB Mathematics and Physics

are required for all Physics programmes. Applicants with other qualifications (for example the Access to Higher Education Diploma or Open University credits) may need to pass an AL-style mathematics test to demonstrate ability. This test will be undertaken as part of an interview.

Applicants who meet our entry criteria will be invited to visit the Department between November and March. Places are not normally offered to applicants who do not participate in an interview.

10.2. Further Details

Further details, including typical offers and English language requirements for International students are published on the University's Admissions webpages:

Undergraduate Study > Subjects > Physics and Astronomy

11. Regulation of Assessment and Academic Standards
Each academic programme in the University is subject to an agreed College assessment and marking strategy, underpinned by institution-wide assessment procedures. The security of assessment and academic standards is further supported through the appointment of External Examiners for each programme. External Examiners have access to draft papers, course work and examination scripts. They are required to attend the Board of Examiners and to provide an annual report. Annual External Examiner reports are monitored at both College and University level. Their responsibilities are described in the University's code of practice. For details see: University of Exeter TQA Manual

11. Regulation of Assessment and Academic Standards

Each academic programme in the University is subject to an agreed College assessment and marking strategy, underpinned by institution-wide assessment procedures.

The security of assessment and academic standards is further supported through the appointment of External Examiners for each programme. External Examiners have access to draft papers, course work and examination scripts. They are required to attend the Board of Examiners and to provide an annual report. Annual External Examiner reports are monitored at both College and University level. Their responsibilities are described in the University's code of practice. For details see:

University of Exeter TQA Manual

12. Indicators of Quality and Standards
Certain programmes are subject to accreditation and/or review by professional and statutory regulatory bodies (PSRBs). This programme is accredited by the Institute of Physics. For more information, refer to the Physics Handbook: Quality and Accreditation of Programmes and Awards

14	Awarding Institution	University of Exeter
15	Lead College / Teaching Institution	College of Engineering, Mathematics and Physical Sciences
16	Partner College / Institution	N/A
17	Programme accredited/validated by	Institute of Physics (IOP)
18	Final Award(s)	MPhys (Hons)
19	UCAS Code (UG programmes)	F3FM
20	NQF Level of Final Awards(s):	7
21	Credit (CATS and ECTS)	480 Credits (240 ECTS)
22	QAA Subject Benchmarking Group (UG and PGT programmes)	Physics, Astronomy and Astrophysics

23	Origin Date	February 8th 2023	Last Date of Revision:	May 11th 2023

Physics with Astrophysics (2023)

1. Programme Title:

Physics with Astrophysics

NQF Level:

7

2. Description of the Programme (as in the Business Approval Form)

3. Educational Aims of the Programme

4. Programme Structure

5. Programme Modules

Stage 1

Stage 2

Stage 3

Stage 4

6. Programme Outcomes Linked to Teaching, Learning & Assessment Methods

A Specialised Subject Skills & Knowledge

Learning & Teaching Activities

Assessment Methods

B Academic Discipline Core Skills & Knowledge

Learning & Teaching Activities

Assessment Methods

C Personal / Transferable / Employment Skills & Knowledge

Learning & Teaching Activities

Assessment Methods

7. Programme Regulations

8. College Support for Students and Students' Learning

10. Admission Criteria

11. Regulation of Assessment and Academic Standards

12. Indicators of Quality and Standards