. "Project"@en . . "60.0" . "#### Prerequisites\n\n* Foundations of Physics 3A (PHYS3621) AND (Discovery Skills in Physics (PHYS1101) or Laboratory Skills and Electronics (PHYS2641) or Laboratory Skills and Electronics 3 (PHYS3681)).\n\n#### Corequisites\n\n* None.\n\n#### Excluded Combination of Modules\n\n* None.\n\n#### Aims\n\n* This module is designed primarily for students studying Department of Physics or Natural Sciences degree programmes.\n* It provides experience of work in a research environment on a topic at the forefront of developments in a branch of either physics, applied physics, theoretical physics or astronomy, and develops transferable skills for the oral and written presentation of research.\n\n#### Content\n\n* The syllabus contains:\n* A research-based project carried out within one of the Department's research groups.\n* In the case of industrially linked projects, some time may be spent at the industrial site.\n* Projects may involve small groups of students working in a team.\n* Presentation and communication skills.\n* Research methods and techniques, scientific writing and presentation, interviews.\n\n#### Learning Outcomes\n\nSubject-specific Knowledge:\n\n* Having studied this module students will have an understanding of the techniques used in either theoretical or experimental physics together with an appreciation of their applicability to a research project.\n\nSubject-specific Skills:\n\nKey Skills:\n\n* Students will be able to work independently and develop an effective work plan.\n* They will be able to solve problems with originality and be able to complete tasks efficiently.\n* They will be able to resolve complex problems by identifying creative solutions.\n* They will have the facility to express problems and communicate their solution via oral and written means.\n* They will have the confidence to advance and extend knowledge through the development of an independent learning ability and personal responsibility.\n* They will have further developed communication and oral presentation skills, including written communication of scientific concepts to a general audience.\n\n#### Modes of Teaching, Learning and Assessment and how these contribute to the learning outcomes of the module\n\n* The project is based in a research group and may involve extensive private study, work on one or more computers or practical work in one of the research laboratories.\n* In the case of industrially linked projects, some time may be spent at the industrial site.\n* Supervisors monitor progress and provide guidance on the development of the project during weekly meetings.\n* Students will be able to obtain further help in their project by approaching their supervisors and/or other members of the appropriate research group.\n* The seminars provide formal instruction on communication skills, both written and oral, that are then reinforced by the project supervisors during the weekly meetings.\n* The seminars include training sessions on general computing, testing and debugging. The drop-in sessions are designed to allow each student to obtain programming help and guidance through discussions with computing demonstrators.\n* Progress is further monitored by a formatively assessed interim project progress report written over the Christmas vacation.\n* Together with the project seminar, this provides opportunities for feedback and for the students to gauge their progress.\n* Student performance is summatively assessed through technical performance during the project, through a formal final report on the project, through the project seminar and via an oral examination on the project report.\n\nMore information at: https://apps.dur.ac.uk/faculty.handbook/2023/UG/module/PHYS4213" . . "Presential"@en . "TRUE" . . "Project Management"@en . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . "Master in Physics and Astronomy"@en . . "https://www.durham.ac.uk/study/courses/physics-and-astronomy-ff3n/" . "120"^^ . "Presential"@en . "**Course details**\nIf you are fascinated by the relationship between mathematics, the cosmos and the scientific world this MPhys could be for you. This integrated Master's degree is the first step towards Chartered Physicist status. It will suit those looking for an accredited course that leads to higher level education or a research role in physics, while also providing the knowledge, analytical and problem-solving skills for a career in the sciences, engineering, finance or IT.\n\nPhysics degrees at Durham offer a high level of flexibility. We offer four Institute of Physics accredited courses - MPhys qualifications in Physics, Physics and Astronomy, and Theoretical Physics and the three-year BSc in Physics - which follow the same core curriculum in Year 1.\n\nSubject to the optional modules chosen, it is possible to switch to one of the other courses until the end of the second year. You can also apply for a one-year work placement or study abroad opportunity with one of our partner organisations, increasing the course from four years to five or substituting the existing Year 3.\n\nThe first year lays the foundation in physics theory, mathematical skills and laboratory skills that you will need to tackle more complex content later in the course. From Year 2 the focus on astronomy and astrophysics increases.\n\nAs you progress through the course, learning is more closely aligned to real-world issues through project work and optional modules that are tailored to your interests and aspirations. Your knowledge is further extended with a project based on a live research topic, and higher-level modules which take your study of physics and astronomy to a greater depth.\n\n**Course structure**\n*Year 1*\nCore modules:\nFoundations of Physics introduces classical aspects of wave phenomena and electromagnetism, as well as basic concepts in Newtonian mechanics, quantum mechanics, special relativity and optical physics.\n\nDiscovery Skills in Physics provides a practical introduction to laboratory skills development with particular emphasis on measurement uncertainty, data analysis and written and oral communication skills. It also includes an introduction to programming.\n\nExamples of optional modules:\nSingle Mathematics\nLinear Algebra\nCalculus.\n\n*Year 2*\nCore modules:\nFoundations of Physics A develops your knowledge of quantum mechanics and electromagnetism. You will learn to apply the principles of physics to predictable and unpredictable problems and produce a well-structured solution, with clear reasoning and appropriate presentation.\n\nFoundations of Physics B extends your knowledge of thermodynamics, condensed matter physics and optics.\n\nStars and Galaxies introduces astronomy and astrophysics. You will develop an understanding of the basic physics of stellar interiors and learn why we see stars of differing colours and brightness. The module extends your knowledge of pulsating and binary stars and introduces galactic and extragalactic astronomy.\n\nMathematical Methods in Physics provides the necessary mathematical knowledge to successfully tackle the Foundations of Physics modules. It covers vectors, vector integral and vector differential calculus, multivariable calculus and orthogonal curvilinear coordinates, Fourier analysis, orthogonal functions, the use of matrices, and the mathematical tools for solving ordinary and partial differential equations occurring in a variety of physical problems.\n\nLaboratory Skills and Electronics builds lab-based skills, such as experiment planning, data analysis, scientific communication and specific practical skills. It aims to teach electronics as a theoretical and a practical subject, to teach the techniques of computational physics and numerical methods and to provide experience of a research-led investigation in physics in preparation for post-university life.\n\nExamples of optional modules:\nTheoretical Physics\nPhysics in Society.\n\n*Year 3*\nCore modules:\nFoundations of Physics A further develops your knowledge to include quantum mechanics and nuclear and particle physics. You will learn to apply the principles of physics to complex problems and produce a well-structured solution, with clear reasoning and appropriate presentation.\n\nFoundations of Physics B extends your knowledge to include statistical physics and condensed matter physics.\n\nPlanets and Cosmology explains the astrophysical origin of planetary systems and the cosmological origin of the Universe. You will learn about the formation and workings of our Solar System, its orbital dynamics and the basic physics of planetary interiors and atmospheres.\n\nThe Computing Project is designed to develop your computational and problem-solving skills. You work on advanced computational physics problems using a variety of modern computing techniques and present your findings in a project report, poster and oral presentation.\n\nExamples of optional modules:\nTeam Project\nAdvanced Laboratory\nMathematics Workshop\nPhysics into Schools\nTheoretical Physics\nCondensed Matter Physics\nModern Atomic and Optical Physics.\n\n*Year 4*\nCore modules:\nThe research-based MPhys Project provides experience of work in a research environment on a topic at the forefront of developments in a branch of either physics, applied physics, theoretical physics or astronomy, and develops transferable skills for the oral and written presentation of research. The project can be carried out individually or as part of a small group in one of the Department's research groups or in collaboration with an external organisation.\n\nAdvanced Astrophysics covers astronomical techniques and radiative processes in astrophysics. This module provides a working knowledge of the advanced optical techniques used in modern astronomy and of the radiative processes that generate the emission that is studied in a wide range of astronomical observations.\n\nTheoretical Astrophysics examines cosmic structure formation and general relativity. This module provides an overview of our current understanding of the formation and evolution of cosmic structure and an introduction to Einstein's general theory of relativity.\n\nExamples of optional modules:\nAtoms, Lasers and Qubits\nAdvanced Theoretical Physics\nAdvanced Condensed Matter Physics\nParticle Theory\nTheoretical Physics\nCondensed Matter Physics\nModern Atomic and Optical Physics.\nAdditional pathways\nStudents on the MPhys in Physics and Astronomy can apply to be transferred onto either the 'with Year Abroad' or 'with Placement' pathway during the second year. Places on these pathways are in high demand and if you are chosen you can choose to extend your course from four years to five, or substitute the existing Year 3.\n\n**Placement**\nYou may be able to take a work placement. Find out more in https://www.durham.ac.uk/study/undergraduate/how-to-apply/study-options/placements/.\n\nModules details: https://apps.dur.ac.uk/faculty.handbook/2023/UG/programme/FF3N"@en . . . "4"@en . "FALSE" . . "Master"@en . "Both" . "9250.00" . "British Pound"@en . "30500.00" . "Recommended" . "**Career opportunities**\n*Physics*\nWe seek to develop the practical and intellectual skills sought by employers and we are regularly ranked among the country's top performers for graduate employment. Our graduates have progressed to careers in business, industry, commerce, research, management and education, and typically more than fifth of our graduates go on to study for higher degrees.\n\nThe Department also has an impressive track record of spin-out technology companies that commercialise our knowledge in areas of semiconductors, composites and advanced instrumentation. Examples of high-profile employers include BT, Procter & Gamble, Rolls Royce and BAE Systems.\n\nOf those students who graduated in 2019:\n83% are in paid employment or further study 15 months after graduation across all our programmes\n\nOf those in employment:\n81% are in high skilled employment\nWith an average salary of £34,000.\n\n(Source: HESA Graduate Outcomes Survey. The survey asks leavers from higher education what they are doing 15 months after graduation. Further information about the Graduate Outcomes survey can be found here www.graduateoutcomes.ac.uk)"@en . "2"^^ . "TRUE" . "Downstream"@en . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .