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Masters Degrees (Laser Physics)

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Take advantage of one of our 100 Master’s Scholarships to study Laser Physics at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Laser Physics at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

The MSc by Research Laser Physics enables students to pursue a one year individual programme of research. The Laser Physics programme would normally terminate after a year. However, under appropriate circumstances, this first year of research can also be used in a progression to Year 2 of a PhD degree.

You will be fully integrated into one of our established research groups and participate in research activities such as seminars, workshops, laboratories, and field work.

Key Features

Swansea is a research led University to which the Physics department makes a significant contribution, meaning that as a postgraduate Physics student you will benefit from the knowledge and skills of internationally renowned academics.

The Department received top ratings of 4* and 3* in the 2008 RAE, which classified our research as World-leading or Internationally excellent in terms of its originality, significance and rigour.

The two main research groups within the Department of Physics currently focus on the following areas of research:

Atomic, Molecular and Quantum Physics Group

Fundamental Atomic Physics
Condensed Matter and Material Physics
Analytical Laser Spectroscopy
Particle Physics Theory Group

String theory, quantum gravity and the AdS/CFT correspondence
Lattice gauge theories, QCD
Supersymmetric field theory, perturbative gauge theory
Field Theory in curved spacetime
Physics beyond the standard model

Links with Industry

Our two research groups, Particle Physics Theory (PPT) and Atomic, Molecular and Quantum Physics (AMQP), deliver impact with commercial benefits both nationally and internationally, complemented by a public engagement programme with a global reach.

Economic impacts are realised by the Department’s Analytical Laser Spectroscopy Unit (ALSU) which, since 1993, has worked with companies developing products eventually sold to customers in the nuclear power industry and military, both in the UK and overseas, and in the global aerospace industry. Computational particle physics work performed by the PPT group has spun-off a computer benchmarking tool, BSMBench, used by several leading software outfits, and has led to the establishment of a start-up company.

The AMQP group’s work on trapping and investigating antihydrogen has generated great media interest and building on this we have developed a significant and on-going programme of public engagement. Activities include the development of a bespoke software simulator (Hands on Antihydrogen) of the antimatter experiment for school students.

Facilities

As a student of the Laser Physics programme in the Department of Physics you will have access to the following Specialist Facilities:

Low-energy positron beam with a high field superconducting magnet for the study of
positronium
CW and pulsed laser systems
Scanning tunnelling electron and nearfield optical microscopes
Raman microscope
CPU parallel cluster
Access to the IBM-built ‘Blue C’ Super computer at Swansea University and is part of the shared use of the teraflop QCDOC facility based in Edinburgh

Research

The Physics Department carries out world-leading research in experimental and theoretical physics.

The results of the Research Excellence Framework (REF) 2014 show that over 80% of the research outputs from both the experimental and theoretical groups were judged to be world-leading or internationally excellent.

Research groups include:

AMQP Group

The Atomic, Molecular and Quantum Physics Group comprises academic staff, postdoctoral officers and postgraduate research students. Its work is supported by grants from EPSRC, the EU, The Royal Society, the Higher Education Funding Council for Wales and various industrial and government sources. There are two main fields of research: Atomic, Molecular and Laser Physics and Nanoscale Physics.

PPT Group

The Particle Physics Theory Group has fourteen members of staff, in addition to postdoctoral officers and research students. It is the fourth largest particle physics theory group in the UK, and is supported mainly by STFC, but also has grants from EPSRC, the EU, Royal Society and Leverhulme Trust. The group recently expanded by hiring two theoretical cosmologists (Ivonne Zavala and Gianmassimo Tasinato). There are five main fields of research: Quantum Field Theory, Strings, Lattice Field Theory, Beyond the Standard Model Physics and Theoretical Cosmology.

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Take advantage of one of our 100 Master’s Scholarships to study Nanotechnology (Physics) at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Nanotechnology (Physics) at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

The MSc by Research Nanotechnology (Physics) enables students to pursue a one year individual programme of research. The Nanotechnology (Physics) programme would normally terminate after a year. However, under appropriate circumstances, this first year of research can also be used in a progression to Year 2 of a PhD degree.

For MSc by Research in Nanotechnology (Physics) programme you will be guided by internationally leading researchers through an extended one-year individual research project. There is no taught element. The Nanotechnology (Physics) programme has a recommended initial research training module (Science Skills & Research Methods), but otherwise has no taught element and is most suitable for you if you have an existing background in geography or cognate discipline and are looking to pursue a wholly research-based programme of study.

As a student of the MSc by Research in Nanotechnology (Physics) you will be fully integrated into one of our established research groups and participate in research activities such as seminars, workshops, laboratories, and field work.

Key Features

Swansea is a research led University to which the Physics department makes a significant contribution, meaning that as a postgraduate Physics student you will benefit from the knowledge and skills of internationally renowned academics.

The Department received top ratings of 4* and 3* in the 2008 RAE, which classified our research as World-leading or Internationally excellent in terms of its originality, significance and rigour.

Links with Industry

Our two research groups, Particle Physics Theory (PPT) and Atomic, Molecular and Quantum Physics (AMQP), deliver impact with commercial benefits both nationally and internationally, complemented by a public engagement programme with a global reach.

Economic impacts are realised by the Department’s Analytical Laser Spectroscopy Unit (ALSU) which, since 1993, has worked with companies developing products eventually sold to customers in the nuclear power industry and military, both in the UK and overseas, and in the global aerospace industry. Computational particle physics work performed by the PPT group has spun-off a computer benchmarking tool, BSMBench, used by several leading software outfits, and has led to the establishment of a start-up company.

The AMQP group’s work on trapping and investigating antihydrogen has generated great media interest and building on this we have developed a significant and on-going programme of public engagement. Activities include the development of a bespoke software simulator (Hands on Antihydrogen) of the antimatter experiment for school students.

Facilities

As a student of the MSc by Research in Nanotechnology (Physics) in the Department of Physics you will have access to the following Specialist Facilities:

Low-energy positron beam with a high field superconducting magnet for the study of
positronium
CW and pulsed laser systems
Scanning tunnelling electron and nearfield optical microscopes
Raman microscope
CPU parallel cluster
Access to the IBM-built ‘Blue C’ Super computer at Swansea University and is part of the shared use of the teraflop QCDOC facility based in Edinburgh

Research

The Physics Department carries out world-leading research in experimental and theoretical physics.

The results of the Research Excellence Framework (REF) 2014 show that over 80% of the research outputs from both the experimental and theoretical groups were judged to be world-leading or internationally excellent.

This MSc by Research in Nanotechnology comes under the Nano-physics and the life sciences research area at Swansea. The fundamental understanding of the electronic, structural, chemical and optical properties of materials on the nano-scale is essential for advances in nanotechnology, in particular the development of new devices via the incorporation of novel materials. Advances in experimental physics underpin these developments via characterisation and quantification of quantum phenomena which dominate at these length scales.

The Nanotechnology research concentrates on two main areas: determining properties of materials (e.g., graphene) on the nano-scale using scanning probe based techniques; the development of imaging and laser based spectroscopic techniques to study biological samples (e.g., imaging of cellular components and bacteria).

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Applying the laws of physics in real-life situations, ranging from measuring brain activity to designing new materials and investigating space objects. Read more
Applying the laws of physics in real-life situations, ranging from measuring brain activity to designing new materials and investigating space objects .

Would you rather specialise in pure physics or discover the interface between physics and astronomy, mathematics, chemistry or biology? The choice is yours. At Radboud University, you can choose from six specialisations and within each specialisation you’ll have plenty of room to customise your programme. We guarantee the highest quality for all specialisation programmes, resulting in number one rates by the Dutch ‘Keuzegids Masters’ for three years running.

In your internship(s), you can dive into theoretical physics or perform your own experiments: discover new material properties in Europe’s highest magnetic fields or with unique free electron lasers, study space objects with the telescopes on top of the Huygens Building or unravel brain activity with MRIs. It’s all possible on the Radboud campus. That’s why many international physicists come here to perform their experiments. Take Andre Geim and Konstantin Novoselov, who revealed the amazing properties of graphene in our High Field Magnet Laboratory. In 2010, they received the Nobel Prize in Physics for those discoveries.

See the website http://www.ru.nl/masters/physicsandastronomy

Specialisations of Physics and Astronomy

- Particle and Astrophysics
In this Master’s specialisation you’ll unravel questions like: What are the most elementary particles that the universe consists of? What did our universe look like in the earliest stages of its existence? And how will it evolve? One of the topics is the Higgs particle, which is partially a Nijmegen discovery.

- Physics of Molecules and Materials
This specialisation focuses on the structure and properties of materials. You’ll work at the ‘terra incognita’ between quantum and classical physics, which is of great importance for designing next-generation materials and devices.

- Neuroscience
In this specialisation you’ll use your physics background to understand the communication between neurons in the brain. This fundamental knowledge can be applied in all kinds of devices, including hearing aids or Google glasses.

- Science in Society
This specialisation will equip you with the tools and skills to become a professional intermediary between science and society. You’ll learn to analyse (governmental) science communication and connect scientific knowledge with divergent perspectives and interests of various stakeholders.

- Science, Management and Innovation
This specialisation will teach you what is happening in the world of business and public administration, how innovation is managed in company strategies, how government designs policy and how that interacts with societal challenges.

- Science and Education (in Dutch)
Do you want to become a secondary school teacher in the Netherlands? In this Dutch-taught specialisation you’ll get the necessary didactic background and extensive experience in the classroom.

Why study Physics and Astronomy at Radboud University?

- It’s the best Master’s programme of its kind in the Netherlands, according to the Keuzegids Masters.
- Teaching takes place in a stimulating, collegial setting with small groups. This ensures that at Radboud University you’ll get plenty of one-on-one time with your internship supervisor.
- We have a multidisciplinary approach: you not only can specialise in Physics, but also in astrophysics, biophysics, mathematical physics, chemical physics or materials science.
- You’ll spend one year on research, and thus get an extensive experience in scientific methods.
- Radboud University hosts multiple state-of-the-art research facilities, such as the High Field Magnet Laboratory , FELIX laser laboratory, Nanolab and neuroimaging facilities (MRI, MEG, EEG, TMS). We also participate in the LHC particle accelerator in Geneva, the Pierre Auger Observatory in Argentina and various other large-scale research projects.
- On average, our graduates find a job within 2 months after graduating. A majority of these jobs are PhD positions at universities in the Netherlands and abroad.

Quality label

For the third time in a row, this programme was rated number one in the Netherlands in the Keuzegids Masters 2015 (Guide to Master's programmes).

Career prospects

All specialisations of this Master’s programme are an excellent preparation for a career in research, either at a university, at an institute or at a company. However, many of our students end up in other business or government positions as well. Whatever job you aspire, you can certainly make use of the fact that you have learned to:
- Think in an abstract way
- Solve complex problems
- Make accurate approximations
- Combine theory and experiments

PhD positions

If you would like to have a career in science, it’s possible to apply for a PhD position at Radboud University. Of course, you can also apply at any other university anywhere in the world.

Positions in business or governmental organisations

To get an idea the various career opportunities, a sample of jobs performed by our alumni:
- Actuarial trainee at Talent & Pro
- Consultant at Accenture
- ECO Operations Manager at Ofgem
- Scientist at SRON Netherlands Institute for Space Research
- Technology strategy Manager at Accenture
- Consultant Billing at KPN
- Communications advisor at the Foundation for Fundamental Research on Matter (FOM)
- Systems analysis engineer at Thales
- Technical consultant at UL Transaction Security
- Business analyst at Capgemini

See the website http://www.ru.nl/masters/physicsandastronomy

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This is a vocational course in applied physics for anyone with a background in the physical sciences or engineering. You can choose classes relevant to your career interests from a wide range of topics including. Read more

Why this course?

This is a vocational course in applied physics for anyone with a background in the physical sciences or engineering.

You can choose classes relevant to your career interests from a wide range of topics including:
- high-power microwave technology
- laser-based particle acceleration and enabled applications
- physics and the life sciences
- materials and solid state physics
- photonics
- quantum optics and quantum information technology

You‘ll put the knowledge gained in the taught classes to use on a research project. You can design the project to fit in with your interests and career plans.

The course gives you the opportunity to explore and master a wide range of applied physics skills. It teaches you transferable, problem-solving and numeracy skills that are widely sought after across the commercial sector.

See the website https://www.strath.ac.uk/courses/postgraduatetaught/appliedphysics/

You’ll study

You’ll have two semesters of taught classes made up of compulsory and optional modules. This is followed by a three-month research project.

Facilities

This course is run by our Department of Physics. The department’s facilities include:
- cutting-edge high-power laser and particle acceleration research with SCAPA, enabling generation of radiation from the terahertz to - the X-ray region, and biomedical applications
- the Ultrafast Chemical Physics lab with state-of-the-art femtosecond laser systems for multi-dimensional IR spectroscopy
- a scanning electron microscopy suite for analysis of hard and soft matter
- access to top-of-the-range high-performance and parallel computer facilities
- state-of-the-art high-power microwave research facility in the Technology & Innovation Centre
- advanced quantum optics and quantum information labs
- several labs researching optical spectroscopy and sensing

Pre-Masters preparation course

The Pre-Masters Programme is a preparation course for international students (non EU/UK) who do not meet the entry requirements for a Masters degree at the University of Strathclyde. The Pre-Masters programme provides progression to a number of degree options

To find out more about the courses and opportunities on offer visit isc.strath.ac.uk or call today on +44 (0) 1273 339333 and discuss your education future. You can also complete the online application form. To ask a question please fill in the enquiry form and talk to one of our multi-lingual Student Enrolment Advisers today.

Learning & teaching

Our teaching is based on lectures, tutorials, workshops, laboratory experiments and research projects.

Assessment

The final assessment will be based on your performance in examinations, coursework, a research project and, if required, in an oral exam.

What kind of jobs do Strathclyde Physics graduates get?

To answer this question we contacted some of our Physics graduates from all courses to find out what jobs they have. They are working across the world in a number of different roles including:
- Medical Physicist
- Senior Engineer
- Professor
- Systems Engineer
- Treasury Analyst
- Patent Attorney
- Software Engineer
- Teacher
- Spacecraft Project Manager
- Defence Scientist
- Procurement Manager
- Oscar winner

- Success story: Iain Neil
Iain Neil graduated from Strathclyde in Applied Physics in 1977 and is an optical consultant, specialising in the design of zoom lenses for the film industry. He has received a record 12 Scientific and Technical Academy Awards, the most for any living person.

Find information on Scholarships here http://www.strath.ac.uk/search/scholarships/index.jsp

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The course gives you the opportunity to explore and master theoretical, computational and experimental physics skills with wide application. Read more

Why this course?

The course gives you the opportunity to explore and master theoretical, computational and experimental physics skills with wide application.

Our four divisions – Nanoscience, Optics, Plasmas and the Institute of Photonics – all contribute research-based teaching expertise to the course. You can choose taught elements relevant to your career interests from a wide range of topics, including:
- theoretical & computational physics
- quantum optics and quantum information
- complexity science
- physics and the life sciences
- solid-state physics
- plasma physics

The knowledge you gain in the taught components is then put to use in a cutting-edge research project, which can be theoretical, computational or experimental.

See the website https://www.strath.ac.uk/courses/postgraduatetaught/advancedphysics/

You’ll study

You’ll have two semesters of taught classes made up of compulsory and optional modules. This is followed by a three-month research project.

- Facilities
This course is run by the Department of Physics. The department’s facilities include:
- cutting-edge high-power laser research with SCAPA, researching the future of particle accelerators via laser-based acceleration
- the Ultrafast Chemical Physics lab with state-of-the-art femtosecond laser systems for multi-dimensional IR spectroscopy
- access to the top-of-the-range high performance and parallel computer facilities of ARCHIE-WeSt
- a scanning electron microscopy suite for analysis of hard and soft matter
- new high-power microwave research facility in the Technology & Innovation Centre
- advanced quantum optics and quantum information labs

English language

IELTS 6.0 is required for all non-English speakers.

Learning & teaching

Our teaching is based on lectures, tutorials, workshops, laboratory experiments, and research projects.

Assessment

The final assessment will be based on your performance in examinations, coursework, a research project and, if required, in an oral examination.

Careers

A Masters degree in physics prepares you for a wide and versatile range of careers in science and engineering as well as all areas of management, financial services, etc. Many graduates proceed to a PhD.

Strathclyde physics graduates are working across the world in a number of different roles including:
- Medical Physicist
- Senior Engineer
- Professor
- Systems Engineer
- Treasury Analyst
- Patent Attorneys
- Software Engineer
- Teacher
- Spacecraft Project Manager
- Defence Scientist
- Procurement Manager
- Oscar winner

Find information on Scholarships here http://www.strath.ac.uk/search/scholarships/index.jsp

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Take advantage of one of our 100 Master’s Scholarships to study Antimatter Physics at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Antimatter Physics at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

The MSc by Research Antimatter Physics enables students to pursue a one year individual programme of research. The Antimatter Physics programme would normally terminate after a year. However, under appropriate circumstances, this first year of research can also be used in a progression to Year 2 of a PhD degree.

You will be fully integrated into one of our established research groups and participate in research activities such as seminars, workshops, laboratories, and field work.

The Physics Department carries out world-leading research in experimental and theoretical physics.
The Atomic, Molecular and Quantum Physics Group (AMQP) at Swansea University comprises academic staff, postdoctoral officers and postgraduate research students. Its work is supported by grants from EPSRC, the EU, The Royal Society, the Higher Education Funding Council for Wales and various industrial and government sources.

The Particle Physics Theory Group (PPT) has fourteen members of staff, as well as postdoctoral officers and research students. It is the fourth largest particle physics theory group in the UK, and is supported mainly by STFC, but also has grants from EPSRC, the EU, the Royal Society and Leverhulme Trust.

Links with Industry

Our two research groups, Particle Physics Theory (PPT) and Atomic, Molecular and Quantum Physics (AMQP), deliver impact with commercial benefits both nationally and internationally, complemented by a public engagement programme with a global reach.

Economic impacts are realised by the Department’s Analytical Laser Spectroscopy Unit (ALSU) which, since 1993, has worked with companies developing products eventually sold to customers in the nuclear power industry and military, both in the UK and overseas, and in the global aerospace industry. Computational particle physics work performed by the PPT group has spun-off a computer benchmarking tool, BSMBench, used by several leading software outfits, and has led to the establishment of a start-up company.

The AMQP group’s work on trapping and investigating antihydrogen has generated great media interest and building on this we have developed a significant and on-going programme of public engagement. Activities include the development of a bespoke software simulator (Hands on Antihydrogen) of the antimatter experiment for school students.

Read less
Physics has always remained and still is at the center of science and technology. The laws of physics that are reached through observations and careful experimentation find applications from the subatomic particles to the astronomic formations such as stars and galaxies. Read more
Physics has always remained and still is at the center of science and technology. The laws of physics that are reached through observations and careful experimentation find applications from the subatomic particles to the astronomic formations such as stars and galaxies. On the other hand, design of advanced technology materials, fabrication of semiconductor devices, the development of optical communication systems have all evolved as applications of physics. Our department has both theoretical and experimental research activites. Quantum information theory, gravitation and condensed matter physics are among our theoretical research interests. On the experimental research side, we have three advanced laboratories where we focus on solid state lasers, optoelectronic and nano-photonic materials and devices. Our M. S. Program aims at teaching fundamental physics at a high level and coupling this knowledge with a research experience in either theoretical or applied physics depending on the interests of the student.

Current faculty projects and research interests:

• Photonic and Laser Materials
• Microphotonics
• Nanophotonics
• Gravitation, Cosmology, and Numerical Relativity
• Mathematical Physics
• Quantum Mechanics and Quantum Information Theory
• Theoretical High Energy Physics
• Quantum Optics, atomic, molecular and optical physics
• Statistical mechanics of biophysical systems

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The M.Sc. in Medical Physics is a full time course which aims to equip you for a career as a scientist in medicine. You will be given the basic knowledge of the subject area and some limited training. Read more
The M.Sc. in Medical Physics is a full time course which aims to equip you for a career as a scientist in medicine. You will be given the basic knowledge of the subject area and some limited training. The course consists of an intense program of lectures and workshops, followed by a short project and dissertation. Extensive use is made of the electronic learning environment "Blackboard" as used by NUI Galway. The course has been accredited by the Institute of Physics and Engineering in Medicine (UK).

Syllabus Outline. (with ECTS weighting)
Human Gross Anatomy (5 ECTS)
The cell, basic tissues, nervous system, nerves and muscle, bone and cartilage, blood, cardiovascular system, respiratory system, gastrointestinal tract, nutrition, genital system, urinary system, eye and vision, ear, hearing and balance, upper limb – hand, lower limb – foot, back and vertebral column, embryology, teratology, anthropometrics; static and dynamic anthropometrics data, anthropometric dimensions, clearance and reach and range of movement, method of limits, mathematics modelling.

Human Body Function (5 ECTS)
Biological Molecules and their functions. Body composition. Cell physiology. Cell membranes and membrane transport. Cell electrical potentials. Nerve function – nerve conduction, nerve synapses. Skeletal muscle function – neuromuscular junction, muscle excitation, muscle contraction, energy considerations. Blood and blood cells – blood groups, blood clotting. Immune system. Autonomous nervous system. Cardiovascular system – electrical and mechanical activity of the heart. – the peripheral circulation. Respiratory system- how the lungs work. Renal system – how the kidneys work. Digestive system. Endocrine system – how hormones work. Central nervous system and brain function.

Occupational Hygiene (5 ECTS)
Historical development of Occupational Hygiene, Safety and Health at Work Act. Hazards to Health, Surveys, Noise and Vibrations, Ionizing radiations, Non-Ionizing Radiations, Thermal Environments, Chemical hazards, Airborne Monitoring, Control of Contaminants, Ventilation, Management of Occupational Hygiene.

Medical Informatics (5 ECTS)
Bio statistics, Distributions, Hypothesis testing. Chi-square, Mann-Whitney, T-tests, ANOVA, regression. Critical Appraisal of Literature, screening and audit. Patient and Medical records, Coding, Hospital Information Systems, Decision support systems. Ethical consideration in Research.
Practicals: SPSS. Appraisal exercises.

Clinical Instrumentation (6 ECTS)
Biofluid Mechanics: Theory: Pressures in the Body, Fluid Dynamics, Viscous Flow, Elastic Walls, Instrumentation Examples: Respiratory Function Testing, Pressure Measurements, Blood Flow measurements. Physics of the Senses: Theory: Cutaneous and Chemical sensors, Audition, Vision, Psychophysics; Instrumentation Examples: Evoked responses, Audiology, Ophthalmology instrumentation, Physiological Signals: Theory Electrodes, Bioelectric Amplifiers, Transducers, Electrophysiology Instrumentation.

Medical Imaging (10 ECTS)
Theory of Image Formation including Fourier Transforms and Reconstruction from Projections (radon transform). Modulation transfer Function, Detective Quantum Efficiency.
X-ray imaging: Interaction of x-rays with matter, X-ray generation, Projection images, Scatter, Digital Radiography, CT – Imaging. Fundamentals of Image Processing.
Ultrasound: Physics of Ultrasound, Image formation, Doppler scanning, hazards of Ultrasound.
Nuclear Medicine : Overview of isotopes, generation of Isotopes, Anger Cameras, SPECT Imaging, Positron Emitters and generation, PET Imaging, Clinical aspects of Planar, SPECT and PET Imaging with isotopes.
Magnetic Resonance Imaging : Magnetization, Resonance, Relaxation, Contrast in MR Imaging, Image formation, Image sequences, their appearances and clinical uses, Safety in MR.

Radiation Fundamentals (5 ECTS)
Review of Atomic and Nuclear Physics. Radiation from charged particles. X-ray production and quality. Attenuation of Photon Beams in Matter. Interaction of Photons with Matter. Interaction of Charged Particles with matter. Introduction to Monte Carlo techniques. Concept to Dosimetry. Cavity Theory. Radiation Detectors. Practical aspects of Ionization chambers

The Physics of Radiation Therapy (10 ECTS)
The interaction of single beams of X and gamma rays with a scattering medium. Treatment planning with single photon beams. Treatment planning for combinations of photon beams. Radiotherapy with particle beams: electrons, pions, neutrons, heavy charged particles. Special Techniques in Radiotherapy. Equipment for external Radiotherapy. Relative dosimetry techniques. Dosimetry using sealed sources. Brachytherapy. Dosimetry of radio-isotopes.

Workshops / Practicals
Hospital & Radiation Safety [11 ECTS]
Workshop in Risk and Safety.
Concepts of Risk and Safety. Legal Aspects. Fundamental concepts in Risk Assessment and Human Factor Engineering. Risk and Safety management of complex systems with examples from ICU and Radiotherapy. Accidents in Radiotherapy and how to avoid them. Principles of Electrical Safety, Electrical Safety Testing, Non-ionizing Radiation Safety, including UV and laser safety.
- NUIG Radiation Safety Course.
Course for Radiation Safety Officer.
- Advanced Radiation Safety
Concepts of Radiation Protection in Medical Practice, Regulations. Patient Dosimetry. Shielding design in Diagnostic Radiology, Nuclear Medicine and Radiotherapy.
- Medical Imaging Workshop
Operation of imaging systems. Calibration and Quality Assurance of General
radiography, fluoroscopy systems, ultrasound scanners, CT-scanners and MR scanners. Radiopharmacy and Gamma Cameras Quality Control.

Research Project [28 ECTS]
A limited research project will be undertaken in a medical physics area. Duration of this will be 4 months full time

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The course explores the versatile field of optical technologies which supports many aspects of modern society. Optical technologies are expected to be a key enabling technology of the 21st century. Read more

Why this course?

The course explores the versatile field of optical technologies which supports many aspects of modern society. Optical technologies are expected to be a key enabling technology of the 21st century.

The course is based on the strong record of optical technologies across research divisions in the department of physics and the collaborating institutions:
- Optics Division (Physics)
- Plasma Division (Physics)
- Nanoscience Division (Physics)
- Institute of Photonics
- Centre for Biophotonics
- Department of Electronic & Electrical Engineering

You can choose classes relevant to your career interests from a wide range of topics including:
- photonics and photonic materials
- nanosciences
- optics at the physics-life sciences interface
- laser-based plasma physics
- quantum optics and quantum information technology

You’ll put the knowledge gained in the taught components to use in a cutting-edge research project.

The course gives you the opportunity of exploring and mastering a large range of optical technologies. It enables you to put devices in the context of an optical system and/or application.

See the website https://www.strath.ac.uk/courses/postgraduatetaught/opticaltechnologies/

Who’s the course suitable for?

It’s suitable for those with a science or engineering background wanting to gain a vocational degree or to obtain a solid foundation for an optics-related PhD programme.

It’s also appropriate for those who’ve worked in industry and want to consolidate their future career by further academic studies.

You’ll study

The course consists of two semesters of taught classes followed by a three- month research project.

Facilities

This course is run by the Department of Physics. The department’s facilities include:
- well-equipped optical labs for semiconductor photonics, semiconductor spectroscopy and fluorescence lifetime analysis.
- the Ultrafast Chemical Physics lab with state-of-the-art femtosecond laser systems for multi-dimensional IR spectroscopy
- cutting edge high power laser research with SCAPA, the highest power laser in a UK university
- a scanning electron microscopy suite for analysis of hard and soft matter
- access to top-of-the-range high performance computer facilities
- industry standard cleanroom in the Institute of Photonics

Pre-Masters preparation course

The Pre-Masters Programme is a preparation course for international students (non EU/UK) who do not meet the entry requirements for a Masters degree at University of Strathclyde. The Pre-Masters programme provides progression to a number of degree options.

To find out more about the courses and opportunities on offer visit isc.strath.ac.uk or call today on +44 (0) 1273 339333 and discuss your education future. You can also complete the online application form. To ask a question please fill in the enquiry form and talk to one of our multi-lingual Student Enrolment Advisers today.

Learning & teaching

Our teaching is based on lectures, tutorials, workshops, laboratory experiments, and research projects.

Assessment

The assessment includes written examinations, coursework, presentations and a talk, oral examination and report presenting and defending the research project.

Careers

The course gives you a thorough basis for a successful job in the photonics, optical and life sciences industries. It provides the basis to excel in more interesting and challenging posts.
The course can also be an entry route into an optics-related PhD programme.
Over the years, many of Strathclyde’s optics and photonics graduates have found successful employment at the large variety of local laser and optics companies as well as with national and international corporations.

Find information on Scholarships here http://www.strath.ac.uk/search/scholarships/index.jsp

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The Masters in Astrophysics gives you an understanding of the principles and methods of modern astrophysics at a level appropriate for a professional physicist. Read more
The Masters in Astrophysics gives you an understanding of the principles and methods of modern astrophysics at a level appropriate for a professional physicist.

Why this programme

◾The School has a major role in the award winning NASA RHESSI X-ray mission studying solar flares and in several other forthcoming international space missions such as ESA’s Solar Orbiter.
◾The School plays a world-leading role in the design and operation of the worldwide network of laser interferometers leading the search for gravitational waves.
◾Physics and Astronomy at the University of Glasgow is ranked 3rd in Scotland (Complete University Guide 2017).
◾You will gain the theoretical, observational and computational skills necessary to analyse and solve advanced astrophysics problems, providing you with an excellent foundation for a career of scientific leadership in academia or industry.
◾You will develop transferable skills that will improve your career prospects, such as project management, team-working, advanced data analysis, problem-solving, critical evaluation of scientific literature, advanced laboratory and computing skills, and how to effectively communicate with different audiences.
◾You will benefit from direct contact with our group of international experts who will teach you cutting-edge physics and supervise your projects.
◾With a 93% overall student satisfaction in the National Student Survey 2016, Physics and Astronomy at Glasgow continues to meet student expectations combining both teaching excellence and a supportive learning environment.

[Modes of delivery of the MSc in Astrophysics include lectures, seminars and tutorials and allow students the opportunity to take part in lab, project and team work.

The programme draws upon a wide range of advanced Masters-level courses. You will have the flexibility to tailor your choice of optional courses and project work to a variety of specific research topics and their applications in the area of astrophysics.

Core courses include
◾Advanced data analysis
◾General relativity and gravitation (alternate years, starting 2018–19)
◾Gravitational wave detection
◾Plasma theory and diagnostics (alternate years, starting 2017–18)
◾Pulsars and supernovae (alternate years, starting 2018–19)
◾Research skills
◾Statistical astronomy (alternate years, starting 2017–18)
◾The Sun's Atmosphere
◾Extended project

Optional courses include

◾Advanced electromagnetic theory
◾Applied optics
◾Circumstellar matter (alternate years, starting 2017-18)
◾Cosmology (alternate years, starting 2018–19)
◾Dynamics, electrodynamics and relativity
◾Exploring planetary systems (alternate years, starting 2018-19)
◾Galaxies (alternate years, starting 2017-18)
◾Instruments for optical and radio astronomy (alternate years, starting 2018-19)
◾Statistical mechanics
◾Stellar astrophysics (alternate years, starting 2017–18)

For further information on the content of individual courses please see Honours and Masters level courses.

Industry links and employability

-◾The School of Physics and Astronomy is highly active in research and knowledge transfer projects with industry. Our Masters students have regular opportunities to engage with our industrial collaborators through informal visits, guest lectures and workshops.
◾You will also benefit from our membership of the Scottish Universities Physics Alliance. The alliance brings together internationally leading physics research across Scotland to form the largest physics grouping in the UK.
◾Our staff and students come from all around the world providing a truly global experience. The School of Physics and Astronomy is committed to providing an equitable environment for study and work, in line with the principles of Project Juno of the Institute of Physics. This was recognised in 2011 by the award of Juno Champion status. We also have a strong programme of talks and seminars given by experts from the UK and abroad, which will give you the chance of broadening your knowledge in many other areas of physics and astronomy.

For further information please visit:

Scottish Universities Physics Alliance
Project Juno of the Institute of Physics
The award of Juno Champion status

Career prospects

Career opportunities include academic research, based in universities, research institutes, observatories and laboratory facilities; industrial research in a wide range of fields including energy and the environmental sector, IT and semiconductors, optics and lasers, materials science, telecommunications, engineering; banking and commerce; higher education.

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We offer postgraduate research degrees in Physics at the MPhil and PhD level in all of our major research areas such as Emerging Technology and Materials, Applied Mathematics, and Photoelectron Spectroscopy. Read more
We offer postgraduate research degrees in Physics at the MPhil and PhD level in all of our major research areas such as Emerging Technology and Materials, Applied Mathematics, and Photoelectron Spectroscopy.

We supervise MPhil students whose interests match the expertise we have in our four main research themes.

Condensed matter and nanoscale physics

We research electronic, optical, structural and magnetic properties of novel solid-state materials, particularly novel semi-conductor structures and nanostructured materials such as nanocrystals and nanowires. Theoretical studies use quantum mechanical approaches and involve massively parallel supercomputing.

Our development of new approaches to quantum modelling is changing the size and complexity of systems that can be modelled. Experimental work takes place at synchrotron facilities in Europe and America and related work takes place with colleagues in the Emerging Technology and Materials (ETM) Group in the School of Electrical, Electronic and Computer Engineering.

Biophysics

Our research in biophysics explores the structure and function of cells with the aim of creating artificial life and building machines based on biological parts. Projects include protocell development and the construction of a cyborg robot. An understanding of biological physics is needed that uses techniques including single molecule manipulation, atomic force microscopy and scanning tunnelling microscopy.

Astrophysics

Galaxies and the interstellar medium, the source of the galactic magnetic field and its influence on the structure of the galaxy form the focus of our research in astrophysics. There is also interest in cosmology, particularly the early universe and its origin in the big bang.

Ultrafast optics

Our research focuses on coherent optical control of atomic collisions in ultracold gases by femtosecond laser light for studies of problems in fundamental physics, such as the measurement of time dependence of the fundamental constants of nature. We also research metrological protocols for characterisation of broadband light, specifically those relating to foundational aspects of quantum mechanics and its application.

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Offered in collaboration with Heriot-Watt University. This programme is aimed at graduates in physics or electrical engineering who seek postgraduate education in photonics to enhance their opportunities in industry/ commerce or in PhD research in photonics. Read more

MSc in Photonics and Optoelectronic Devices

• Offered in collaboration with Heriot-Watt University.

• This programme is aimed at graduates in physics or electrical engineering who seek postgraduate education in photonics to enhance their opportunities in industry/ commerce or in PhD research in photonics.

• The programme is tailored to balance fundamental understanding with industrial relevance.

• You gain an understanding of the fundamental properties of optoelectronic materials and devices with vocational training in modern optics, laser physics and semiconductor physics. You also gain practical experience in the operation of a wide range of laser devices and optoelectronic technologies.

• You develop an appreciation of the widespread practical applications of coherent light sources in communications, material processing and testing, optical processing, medical treatments and diagnostics, and environmental monitoring.

• The industrial project placement occupies 12-14 weeks from late May to August and is assessed in September after the submission of a dissertation.

• The admissions process will be run by the University of St Andrews in 2016 and by Heriot-Watt University in 2017.

Features

* In the UK Research Excellence Framework 2014, the quality of research undertaken by PHYESTA, the joint research School of Physics & Astronomy between the Universities of St Andrews and Edinburgh, was ranked third in the UK and top in Scotland.

* The School has around 40 academic staff, around 70 postdoctoral researchers, including 7 SUPA, EPSRC, STFC and Royal Society Research Fellows, around 80 research students and around 20 students on taught postgraduate courses.

* The MSc course in Photonics and Optoelectronic Devices is offered in collaboration with Heriot-Watt University, allowing students access to the expertise at both sites.

* St Andrews has recently opened £3.7 million of specialist research labs in photonic microfabrication and in high resolution condensed matter physics.

* We are a member of the Scottish Universities Physics Alliance (SUPA), whose Graduate School provides a comprehensive range of graduate level courses in physics and astronomy.

Postgraduate community

The postgraduate community in the School of Physics & Astronomy includes typically ten students in our MSc class, two to ten engineering doctorate students taking taught modules, plus around 80 PhD research students. Students on the MSc course come from all over the world, with a mix of students from the UK, EU and overseas.

You are taught by internationally-leading research experts, and the relatively small size of the School means that there can be real interaction between students and staff. Lecture classes are relatively small, ranging from about 30 students down to groups of just a few. The teaching staff are proud to have the reputation of being accessible to students, and enjoy explaining the excitement of physics and its applications to their students. Well-equipped teaching laboratories allow you to explore the science of photonics in “research mode”, and interact directly with academic staff and the School’s early-career researchers.

Teaching methods

• Teaching comprises lectures, tutorials, and laboratory work.
• The teaching laboratory offers the photonics students a wide choice of experiments.
• Work for lecture modules is assessed largely through examinations whereas the laboratory work is assessed in a continuous manner. Lecture courses are examined at the end of each semester.
• MSc students select their project topic part way through the course. This is assessed by the submission of a dissertation and an oral exam.
• You are also invited to attend relevant research seminars and departmental colloquia given by departmental research staff, specialists from other universities and specialists from industry.

Careers

The MSc programme aims to produce graduates with appropriate knowledge, skills and attitudes to go on to be successful in the photonics area, be it in industrial/commercial positions, or undertaking PhD study in universities.

Typically half the class will start PhD or EngD programmes after graduation, while the other half will take up industrial and commercial positions. Commercial destinations of graduates from a recent year-group include laser development, sales and marketing with consumer/office optoelectronics, product support of optical metrology equipment, theoretical modelling of photonic structures, university teaching, internship with a national laser lab, and semiconductor optoelectronics research.

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Take advantage of one of our 100 Master’s Scholarships to study Cold Atoms and Quantum Optics at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Cold Atoms and Quantum Optics at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

The MSc by Research Cold Atoms and Quantum Optics enables students to pursue a one year individual programme of research. The Cold Atoms and Quantum Optics programme would normally terminate after a year. However, under appropriate circumstances, this first year of research can also be used in a progression to Year 2 of a PhD degree.

As a student of the Cold Atoms and Quantum Optics programme you will be fully integrated into one of our established research groups and participate in research activities such as seminars, workshops, laboratories, and field work.

Swansea is a research led University to which the Physics department makes a significant contribution, meaning that as a postgraduate Physics student you will benefit from the knowledge and skills of internationally renowned academics.

The Department received top ratings of 4* and 3* in the 2008 RAE, which classified our research as World-leading or Internationally excellent in terms of its originality, significance and rigour.

Links with Industry

Our two research groups, Particle Physics Theory (PPT) and Atomic, Molecular and Quantum Physics (AMQP), deliver impact with commercial benefits both nationally and internationally, complemented by a public engagement programme with a global reach.

Economic impacts are realised by the Department’s Analytical Laser Spectroscopy Unit (ALSU) which, since 1993, has worked with companies developing products eventually sold to customers in the nuclear power industry and military, both in the UK and overseas, and in the global aerospace industry. Computational particle physics work performed by the PPT group has spun-off a computer benchmarking tool, BSMBench, used by several leading software outfits, and has led to the establishment of a start-up company.

The AMQP group’s work on trapping and investigating antihydrogen has generated great media interest and building on this we have developed a significant and on-going programme of public engagement. Activities include the development of a bespoke software simulator (Hands on Antihydrogen) of the antimatter experiment for school students.

Facilities

As a postgraduate Cold Atoms and Quantum Optics student in the Department of Physics you will have access to the following Specialist Facilities:

Low-energy positron beam with a high field superconducting magnet for the study of
positronium
CW and pulsed laser systems
Scanning tunnelling electron and nearfield optical microscopes
Raman microscope
CPU parallel cluster
Access to the IBM-built ‘Blue C’ Super computer at Swansea University and is part of the shared use of the teraflop QCDOC facility based in Edinburgh

Research

The Physics Department carries out world-leading research in experimental and theoretical physics.

The results of the Research Excellence Framework (REF) 2014 show that over 80% of the research outputs from both the experimental and theoretical groups were judged to be world-leading or internationally excellent.

Research groups include:

AMQP Group

The Atomic, Molecular and Quantum Physics Group comprises academic staff, postdoctoral officers and postgraduate research students. Its work is supported by grants from EPSRC, the EU, The Royal Society, the Higher Education Funding Council for Wales and various industrial and government sources. There are two main fields of research: Atomic, Molecular and Laser Physics and Nanoscale Physics.

PPT Group

The Particle Physics Theory Group has fourteen members of staff, in addition to postdoctoral officers and research students. It is the fourth largest particle physics theory group in the UK, and is supported mainly by STFC, but also has grants from EPSRC, the EU, Royal Society and Leverhulme Trust. The group recently expanded by hiring two theoretical cosmologists (Ivonne Zavala and Gianmassimo Tasinato). There are five main fields of research: Quantum Field Theory, Strings, Lattice Field Theory, Beyond the Standard Model Physics and Theoretical Cosmology.

Read less
Take advantage of one of our 100 Master’s Scholarships to study Lattice Gauge Theory at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Lattice Gauge Theory at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

The MSc by Research Lattice Gauge Theory enables students to pursue a one year individual programme of research. The Lattice Gauge Theory programme would normally terminate after a year. However, under appropriate circumstances, this first year of research can also be used in a progression to Year 2 of a PhD degree.

You will be fully integrated into one of our established research groups and participate in research activities such as seminars, workshops, laboratories, and field work.

Key Features

Swansea is a research led University to which the Physics department makes a significant contribution, meaning that as a postgraduate Physics student you will benefit from the knowledge and skills of internationally renowned academics.

The Department received top ratings of 4* and 3* in the 2008 RAE, which classified our research as World-leading or Internationally excellent in terms of its originality, significance and rigour.

Links with Industry

Our two research groups, Particle Physics Theory (PPT) and Atomic, Molecular and Quantum Physics (AMQP), deliver impact with commercial benefits both nationally and internationally, complemented by a public engagement programme with a global reach.

Economic impacts are realised by the Department’s Analytical Laser Spectroscopy Unit (ALSU) which, since 1993, has worked with companies developing products eventually sold to customers in the nuclear power industry and military, both in the UK and overseas, and in the global aerospace industry. Computational particle physics work performed by the PPT group has spun-off a computer benchmarking tool, BSMBench, used by several leading software outfits, and has led to the establishment of a start-up company.

The AMQP group’s work on trapping and investigating antihydrogen has generated great media interest and building on this we have developed a significant and on-going programme of public engagement. Activities include the development of a bespoke software simulator (Hands on Antihydrogen) of the antimatter experiment for school students.

Facilities

As a student of Lattice Gauge Theory programme in the Department of Physics you will have access to the following Specialist Facilities:

Low-energy positron beam with a high field superconducting magnet for the study of
positronium
CW and pulsed laser systems
Scanning tunnelling electron and nearfield optical microscopes
Raman microscope
CPU parallel cluster
Access to the IBM-built ‘Blue C’ Super computer at Swansea University and is part of the shared use of the teraflop QCDOC facility based in Edinburgh

Research

The Physics Department carries out world-leading research in experimental and theoretical physics.

The results of the Research Excellence Framework (REF) 2014 show that over 80% of the research outputs from both the experimental and theoretical groups were judged to be world-leading or internationally excellent.

Research groups include:

AMQP Group

The Atomic, Molecular and Quantum Physics Group comprises academic staff, postdoctoral officers and postgraduate research students. Its work is supported by grants from EPSRC, the EU, The Royal Society, the Higher Education Funding Council for Wales and various industrial and government sources. There are two main fields of research: Atomic, Molecular and Laser Physics and Nanoscale Physics.

PPT Group

The Particle Physics Theory Group has fourteen members of staff, in addition to postdoctoral officers and research students. It is the fourth largest particle physics theory group in the UK, and is supported mainly by STFC, but also has grants from EPSRC, the EU, Royal Society and Leverhulme Trust. The group recently expanded by hiring two theoretical cosmologists (Ivonne Zavala and Gianmassimo Tasinato). There are five main fields of research: Quantum Field Theory, Strings, Lattice Field Theory, Beyond the Standard Model Physics and Theoretical Cosmology.

Read less
Take advantage of one of our 100 Master’s Scholarships to study Quantum Fields and String at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Quantum Fields and String at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

The MSc by Research Quantum Fields and String enables students to pursue a one year individual programme of research. The Quantum Fields & String programme would normally terminate after a year. However, under appropriate circumstances, this first year of research can also be used in a progression to Year 2 of a PhD degree.

As a student of the MSc by Research in Quantum Fields and String you will be fully integrated into one of our established research groups and participate in research activities such as seminars, workshops, laboratories, and field work.

Key Features

Swansea is a research led University to which the Physics department makes a significant contribution, meaning that as a postgraduate Physics student you will benefit from the knowledge and skills of internationally renowned academics.

The Department received top ratings of 4* and 3* in the 2008 RAE, which classified our research as world-leading or internationally excellent in terms of its originality, significance and rigour.

Links with Industry

Our two research groups, Particle Physics Theory (PPT) and Atomic, Molecular and Quantum Physics (AMQP), deliver impact with commercial benefits both nationally and internationally, complemented by a public engagement programme with a global reach.

Economic impacts are realised by the Department’s Analytical Laser Spectroscopy Unit (ALSU) which, since 1993, has worked with companies developing products eventually sold to customers in the nuclear power industry and military, both in the UK and overseas, and in the global aerospace industry. Computational particle physics work performed by the PPT group has spun-off a computer benchmarking tool, BSMBench, used by several leading software outfits, and has led to the establishment of a start-up company.

The AMQP group’s work on trapping and investigating antihydrogen has generated great media interest and building on this we have developed a significant and on-going programme of public engagement. Activities include the development of a bespoke software simulator (Hands on Antihydrogen) of the antimatter experiment for school students.

Facilities

As a student of the Quantum Fields and String programme in the Department of Physics you will have access to the following Specialist Facilities:

Low-energy positron beam with a high field superconducting magnet for the study of
positronium
CW and pulsed laser systems
Scanning tunnelling electron and nearfield optical microscopes
Raman microscope
CPU parallel cluster
Access to the IBM-built ‘Blue C’ Super computer at Swansea University and is part of the shared use of the teraflop QCDOC facility based in Edinburgh

Research

The Physics Department carries out world-leading research in experimental and theoretical physics.

The results of the Research Excellence Framework (REF) 2014 show that over 80% of the research outputs from both the experimental and theoretical groups were judged to be world-leading or internationally excellent.

Research groups include:

AMQP Group

The Atomic, Molecular and Quantum Physics Group comprises academic staff, postdoctoral officers and postgraduate research students. Its work is supported by grants from EPSRC, the EU, The Royal Society, the Higher Education Funding Council for Wales and various industrial and government sources. There are two main fields of research: Atomic, Molecular and Laser Physics and Nanoscale Physics.

PPT Group

The Particle Physics Theory Group has fourteen members of staff, in addition to postdoctoral officers and research students. It is the fourth largest particle physics theory group in the UK, and is supported mainly by STFC, but also has grants from EPSRC, the EU, Royal Society and Leverhulme Trust. The group recently expanded by hiring two theoretical cosmologists (Ivonne Zavala and Gianmassimo Tasinato). There are five main fields of research: Quantum Field Theory, Strings, Lattice Field Theory, Beyond the Standard Model Physics and Theoretical Cosmology.

Read less

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