Undergraduate study - 2020 entry

Degree Programme Specification 2019/2020

BSc Honours in Physics with Meteorology

To give you an idea of what to expect from this programme, we publish the latest available information. This information is created when new programmes are established and is only updated periodically as programmes are formally reviewed. It is therefore only accurate on the date of last revision.
Awarding institution: The University of Edinburgh
Teaching institution: The University of Edinburgh
Programme accredited by: This Institute of Physics, Royal Meteorogical Society
Final award: BSc Honours
Programme title: Physics with Meteorology
UCAS code: F304
Relevant QAA subject benchmarking group(s): Physics, Astronomy and Astrophysics
Postholder with overall responsibility for QA: Dr Victoria Martin
Date of production/revision: February 2013

External summary

Physics is the fundamental human endeavour to understand the structure and evolution of the universe. Its scope runs from quarks and leptons, the smallest fragments of the universe, through the material world we perceive directly with our senses, and on to stars and galaxies, and the origins and fate of the universe itself. Meteorology is the application of physical principles to the understanding of the Earth’s atmosphere. Our aim is to guide you through this territory; to share with you our enthusiasm for it; and to equip you with a range of thinking and practical skills which you will need if your subsequent career is in Physics or Meteorology, and which you will value even if it is not.

Studying Physics with Meteorology at Edinburgh allows student to develop:

  • Knowledge and understanding of the physical world and the underlying mathematical methodologies used to describe it; specialising in the study of the Earth’s atmosphere and climate systems;
  • Knowledge of frontier activities capitalising on the strengths of a thriving and diverse research environment;
  • The attitude of mind conducive to critical questioning and creative thinking and the capacity to formulate ideas mathematically and explore them algebraically, graphically, and numerically;
  • To develop an understanding of laboratory experimentation and  critical evaluation of experimental data;
  • To develop the skills required for employment in science-based industry, education and the wide spectrum of professions calling for numerate problem-solvers.

Educational aims of programme

The educational aims of the Physics with Meteorology programme at Edinburgh are:

  • To provide a degree programme with flexibility and choice, accommodating a range of entrance qualifications and experience;
  • To provide a thorough grounding in the fundamental principles underpinning physics and applications in atmospheric and climate physics;
  • To provide a thorough grounding in experimental techniques and the critical analysis of experimental data;
  • To provide exposure to frontier activities, capitalising on the strengths of a thriving and diverse research environment in Edinburgh in both physics and geoscience;
  • To provide a balanced training in the methodologies of modern physics specialising in atmospheric and climate physics;
  • To develop general transferable skills related to IT & computing, problem-solving and communication;
  • To provide a platform for employment in science-based industry, education and the wide spectrum of professions calling for numerate problem-solvers.

Programme outcomes: Knowledge and understanding

By engaging with and completing a degree in Physics with meteorology , graduates will acquire knowledge and understanding of:

  • The core knowledge base of physics comprising: Newtonian Dynamics; Quantum Mechanics; Special Relativity; Electromagnetism & Optics; Thermodynamics and Statistical Mechanics; Atomic, Nuclear & Particle Physics; Condensed Matter Physics;
  • Specialist knowledge in meteorology and atmospheric physics;
  • Balanced training in the methodologies and research skills of Modern Theoretical and Experimental Physics.

Programme outcomes: Graduate attributes - Skills and abilities in research and enquiry

The degree programme aims to develop:

  • An attitude of mind conducive to critical questioning and creative thinking;
  • The capacity to formulate ideas mathematically and explore them algebraically, graphically, and numerically;
  • The ability to harness these skills in tandem with the core knowledge base to solve problems;
  • The ability to assimilate and evaluate advanced literature from a range of diverse sources;
  • The ability to critically analyse experimental data and compare mathematical or computational predictions.

Programme outcomes: Graduate attributes - Skills and abilities in personal and intellectual autonomy

The degree programme aims to develop:

  • Disposition to approach unfamiliar situations with a spirit of critical enquiry;
  • The ability to formulate a physical problem using the appropriate mathematical or experimental methodologies;

Programme outcomes: Graduate attributes - Skills and abilities in communication

The degree programme aims to develop:     

  • The skills to formulate a coherent written and oral presentation based on material gathered and organised independently on a given physics topic;
  • The skills to formulate a mathematical argument or analysis of experimental data and communicate this effectively to peers and educators;
  • The capacity to function effectively as a member or leader of a team working towards joint a joint report and presentation.

Programme outcomes: Graduate attributes - Skills and abilities in personal effectiveness

The degree programme aims to develop:

  • The ability to collaborate effectively and productively with others in the process of inquiry and learning including those with a range of backgrounds and knowledge;
  • The ability to organise their own independent learning to an effective schedule;
  • The commitment to manage time effectively, utilise resources and meet deadlines.

Programme outcomes: Technical/practical skills

The degree programme aims to develop:

  • Confident facility with general IT resources (WWW for learning and information retrieval; e-mail and bulletin boards for communication; word-processing for document preparation);
  • Facility with the Unix operating system;
  • Scientific programming skills in Java;
  • Numerical programming and computer simulation techniques;
  • Computer algebra and symbolic manipulation;
  • The ability to analyse experimental data and assess what can be inferred from it in the light of theoretical expectations and experimental uncertainties.

Programme structure and features

The programme structure is a full time, 600pt Integrated Masters Programme with entry at first or second year level and is fully compliant with the University’s Curriculum Framework and Scottish Qualification Framework.

First Year

Total of 120pt of courses, normally at SCQF Level 8.

Specified courses are:

Physics 1A [20pt] SCQF level 8
Physics 1B [20pt]  SCQF level 8
Mathematics for Physics 1 [20pt] SCQF level 8
Mathematics for Physics 2 [20pt] SCQF level 8
40pt of free choice from Schedules A-Q SCQF level 7/8

 Progression requires 120pt of courses from first year. By concession 40pt of courses may be carried but must not include specified courses.

Second Year

Total of 120pt of courses, normally at SCQF Level 8

 Specified courses are:

Modern Physics [10pt]  SCQF level 8
Linear Algebra and Several Variable Calculus [10pt] SCQF level 8
Physics of Fields and Matter [20pt] SCQF level 8
Dynamics and Vector Calculus [20pt] SCQF level 8
Practical Physics [20pt] SCQF level 8
Meteorology: Atmosphere and Environment [20pt] SCQF level 8
Meteorology: Weather and Climate [20pt]  SCQF level 8

Progression requires 120pt of courses from second year.

Second Year Point of Entry 2 (Fast Track) for suitably qualified students.

Total of 120pt of courses, normally at SCQF Level 8

Specified courses are:

Classical and Modern Physics [20pt]  SCQF level 8
Algebra and Calculus [20pt]  SCQF level 8
Physics of Fields and Matter [20pt] SCQF level 8
Dynamics and Vector Calculus [20pt] SCQF level 8
Practical Physics [20pt] SCQF level 8
Meteorology: Atmosphere and Environment [20pt] SCQF level 8

Progression requires 120pt of courses from second year.

Junior Honours (Third Year)

Total of 120pt of courses, normally at Level 9

Specified courses are:

Fourier Analysis and Statistics [20pt] SCQF level 9
Quantum Mechanics [20pt] SCQF level 9
Thermal Physics [20pt] SCQF level 9
Electromagnetism [20pt] SCQF level 9

Experimental Physics [20pt]

SCQF level 9

either

Computational Modelling [10pt]

or

Numerical Recipes [10pt]

SCQF level 9

Progression requires 120pt of courses at first sit.

Students obtaining 120pt after August re-sits are eligible for Physics BSc (Ord) degree.

Senior Honours (Fourth Year)

Total of 120pt of courses, normally at Level 10 or 11

Specified Courses are:

Atomic and Molecular Physics [10pt] SCQF level 10
Condensed Matter Physics [10pt] SCQF level 10
Atmospheric Dynamics [10pt] SCQF level 10
Atmospheric Physics[10pt] SCQF level 10
Physics of Climate [10pt] SCQF level 10
Physics Skills (BSc) [10pt] SCQF level 10
Team Review Project [10pt] SCQF level 10
Senior Honours Project in [20pt] SCQF level 10
30pt choice from Schedule P and Q SCQF level 10/11
Additional courses from other schedules subject to approval  

Progression requires 120pt of courses at first sit.

Student obtaining 120pt of courses at first sit are by concession permitted to graduate with BSc Honours.

Senior Honours (Fourth Year) from September 2014*

Total of 120pt of courses, normally at Level 10 or 11

Specified Courses are:

Relativity, Nuclear and Particle Physics [20pt]  SCQF level 10
Atmospheric Dynamics [10pt] SCQF level 10
Atmospheric Physics [10pt] SCQF level 10
Physics of Climate [10pt] SCQF level 10

either

Senior Honours Project [20pt]

or

Science Education Placement in Physics [20pt]

SCQF level 10
Physics Skills (BSc) [10pt]  SCQF level 10
40pt free choice from Schedule P and Q SCQF level 10/11
Additional courses from other schedules subject to approvall  

Progression requires 120pt of courses at first sit.

Student obtaining 120pt of courses at first sit are by concession permitted to graduate with BSc Honours.

*This is the proposed structure still under discussion within the School.

Classification of Honours

Honours classification is determined on the 360pt of courses taken in Junior Honours, Senior Honours and Integrated Masters year with years weighted on a 20:40:40 basis. Classification is based on the University Common Marking Scheme.

Equality and Diversity

The School is an active participant in the Institute of Physics JUNO project with “practitioner” status where we monitor and report on equality and diversity across the whole School including activities of academic staff, research staff, post and undergraduate students.

Teaching and learning methods and strategies

The bulk of the teaching programme is conducted through lectures; the class sizes vary from about 250 in pre-honours courses to about 5 in Senior Honours optional courses. This teaching is supported through tutorial sessions and supervised workshops in which students work in groups of about 5; and through study resources generally delivered through WWW. These resources vary in extent and character; they invariably include a detailed syllabus, reading list and problem-set; in some instances they incorporate substantial multimedia material including self-tests and illustrative simulations. First years and Fast Track specific courses offer extensive student support to assist the transition into higher education and develop independent learning skills. These include the use of an in-lecture feedback system, peer assisted learning, tailored problem sheets and extensive student – tutor feedback in extended workshops classes. Computing/IT courses are conducted through supervised sessions in dedicated teaching laboratories in groups of 10-50. Team Projects typically involve teams of about 5 students working largely autonomously.

Teaching and learning workload

You will learn through a mixture of scheduled teaching and independent study. Some programmes also offer work placements.

At Edinburgh we use a range of teaching and learning methods including lectures, tutorials, practical laboratory sessions, technical workshops and studio critiques.

The typical workload for a student on this programme is outlined in the table below, however the actual time you spend on each type of activity will depend on what courses you choose to study.

The typical workload for a student on this programme for each year of study
Start yearTime in scheduled teaching (%)Time in independant study (%)Time on placement (%)
Year 144560
Year 233670
Year 342580
Year 431690

Assessment methods and strategies

Each course has its own assessment criteria appropriate to the specified Learning Objectives of the course as detailed in the on-line course specification. All courses are assessed using the University Common Marking Scheme. Typical modes of assessment through the programme are detailed below:

Pre-Honours: (first and second year)

Lecture based physics and mathematics courses are assessed by end of course written unseen examinations with typical weight of 80% being augmented by weekly hand-in assignments typically weighted at 20%. These are marked throughout the semester and returned with feedback comments typically within 10 days of submission. All semester 1 pre-honours lecture based courses offered examination feedback workshops as the start of semester 2 where students can view their marked scripts and receive personal feedback from the course staff. Class performance and common error feedback on semester 2 examinations are supplied via the School intranet.

Practical and computing classes are assigned by continuous assessment either via written submitted reports, laboratory notebooks or, for computing classes, specified checkpoints assessed during the assigned workshop classes. All submitted reports and notebooks are returned with written feedback, and students receive verbal feedback and advice on computer checkpoints from the assessors.

Honours:

Lecture based physics and mathematics courses are mainly assessed by either end of course, or end of year written unseen examinations. Core courses at Junior Honours are augmented by periodic hand-ins with a typical weight of 10% which are marked throughout the course and are returned with written feedback. The reduction in frequency and weight of these hand-ins compared to pre-honours encourages students to take responsibility for their own learning and time management. In courses with no course work students are encouraged to attempt course questions in advance and seek feedback on their work at the course workshops/tutorials. All students have access to their marked examination scripts via the School Teaching Office.

Practical and computing courses at Junior Honours are assessed as at pre-honours with an experimental laboratory and additional short oral presentation, on which feedback is given. Project work as Senior Honours is assessed via laboratory performance, written report and poster presentation; written feedback is given on all aspects. Team and Group exercises in Research Methods, Team Review and Group Project as assessed by a written group report, group presentation and peer moderation.

Assessment method balance

You will be assessed through a variety of methods. These might include written or practical exams or coursework such as essays, projects, group work or presentations.

The typical assessment methods for a student on this programme are outlined below, however the balance between written exams, practical exams and coursework will vary depending on what courses you choose to study.

The typical assessment methods for a student on this programme for each year of study
Start yearAssessment by written exams (%)Assessment by practical exams (%)Assessment by coursework (%)
Year 174323
Year 263037
Year 353344
Year 4531433

Career opportunities

The BSc programme offers the preparation for a research career in physics either via further academic study, typically towards a PhD or via industrial research.  In addition a wide range of employers recognise that Physics graduates have advanced problem-solving skills and the ability to think logically and critically about complex situations. Add this to a high level of mathematical ability, computing and IT proficiency, and communication skills in written, oral and online media, and Physics graduates have opportunities in a diverse range of careers. Some of our recent graduates have gone on to jobs with Google, the European Space Agency, the BBC, IBM and a variety of other organisations.

Other items

Personal Tutors

Each student is assigned a Personal Tutor who provides both academic and pastoral guidance.  Throughout a student's time at the university the Personal Tutor guides the student in choice of courses and provides general support. Courses are administered and run through the Teaching Organisation in the School.  These produce detailed online course guides for new students and for continuing students.  These guides provide details of courses and also advise students on assessment and general university policy and regulations.