PhysicsFind a programme
|Run by||Faculty of Science|
|Awards available||PhD, MSc by research|
PhD: Three years full-time or equivalent part-time (minimum period of study).
MScR: One year full-time or equivalent part-time (minimum period of study).
|Location of programme||Clifton campus|
|Part-time study available||Yes|
|Start date||Not fixed, but the usual start date is September 2020|
Physics, with its concern for understanding the universe at a fundamental level, lies at the heart of scientific discovery. The School of Physics at Bristol has made major contributions to the field, including the discovery of the pi meson (Nobel Prize in Physics, 1950) and fundamental advances in quantum mechanics.
Researchers within the school explore physics at all scales, from the cosmological to the sub-nuclear, including strong activities in nanoscience and condensed matter physics. The graduate school is an integral part of the School of Physics and is responsible for overseeing all aspects of graduate training, both in academic skills and more generic transferable skills.
Prospective PhD and MSc by Research students are encouraged to contact potential supervisors before making an application. Applications that identify the research group of greatest interest from those listed below will also be accepted.
Fees for 2020/21
We charge an annual tuition fee. Fees for 2020/21 are as follows:
- UK/EU: full-time
- UK/EU: part-time
- Overseas: full-time
- Channel Islands/Isle of Man: full-time
Bench fees: For postgraduate research students who are not funded by UK Research Councils or (specific) UK charities, it is usual to charge a bench fee. A bench fee covers the costs of laboratory consumables, specialist equipment and other relevant costs (e.g. training) for the duration of the programme. The bench fee charged can vary considerably depending on the nature of the programme being undertaken. Details of specific bench fee charges can be provided on request and will made clear in the offer letter sent to applicants.
Fees are subject to an annual review. For programmes that last longer than one year, please budget for up to a five per cent increase in fees each year. Find out more about tuition fees.
University of Bristol students and graduates can benefit from a ten per cent reduction in tuition fees for postgraduate study. Check your eligibility for an alumni scholarship.
Funding for 2020/21
The school provides financial support for PhD students from a number of sources, including research councils, industry and scholarships. For further details, see the School of Physics website.
Further information on funding for prospective UK, EU and international postgraduate students.
A first degree in physics or a related subject, normally at a level equivalent to at least UK upper second-class honours, or a relevant postgraduate master's qualification.
See international equivalent qualifications on the International Office website.
English language requirements
If English is not your first language, you need to meet this profile level:
Further information about English language requirements and profile levels.
Read the programme admissions statement for important information on entry requirements, the application process and supporting documents required.
The school has about 90 teaching and research staff. It is housed in the H H Wills Physics Laboratory that has recently undergone a major investment programme designed to create a new state-of-the-art research environment for both students and staff. The latest facility to be added is a new clean room which is used to process ultrasmall scale electronic/photonic devices. The school is well positioned to carry out cutting-edge research in most major fields of physics.
The School of Physics has a strong international reputation in a wide range of research fields. Our research is organized into themes as follows:
The Astrophysics theme studies a range of important phenomena in the Universe, including extrasolar planets, black holes, galaxies, relativistic jets, clusters of galaxies, plasma processes and cosmology. Observations are made with the world's best ground and space-based telescopes across the entire electromagnetic spectrum, from radio waves up to gamma rays. Theoretical work is closely tied to the interpretation of observational results, and numerical or computational studies make use of the University of Bristol's powerful supercomputing facilities. Students present their work to the wider scientific community at high-profile international conferences and may be involved in one of the major international projects in which the group participates. The group provides a friendly and dynamic research environment. Graduate-level courses and training in observational, data reduction and numerical techniques are offered.
Materials and Devices
This theme covers topics that are driven by innovation and technology – the application of Physics to solve real world problems. The Centre for Device Thermography and Reliability focuses on improving the thermal management, electrical performance and reliability of novel devices, circuits and packaging. The group is develops and applies new techniques for temperature, thermal conductivity, electrical conductivity and traps analysis, especially for microwave and power electronic semiconductor devices, made of wide bandgap materials, such as GaN, SiC and diamond. The Interface Analysis Centre (IAC) is involved in research on materials and material surfaces, including strong activities in nanoscience and nuclear materials. Advances in engineered materials are crucial to the continued vitality of countless industries, and postgraduates in the IAC bridge the gap between science and engineering, becoming expert not only in their area of study but in materials analysis in general. The Nano- and Biophysics area focuses on the development, application and exploitation of novel imaging and characterisation techniques for biology and medicine. A particular strength is in scanning probe microscopy, measuring optical forces at the nanoscale and researching micro- and nanoscale materials of biological relevance. Other key areas of research within Materials and Devices include Surface Physics, working on catalysis and electrodeposited ultrathin films, and Materials for Energy, focusing on the synthesis and characterisation of nanostructured, wide bandgap materials for applications in energy harvesting, radiation detectors and electron sources.
Quantum and Complex Matter
The Quantum and Complex Matter theme studies fundamental problems in condensed matter physics. For example, electrons in a material can order in a huge number of different ways, giving rise to phenomena as diverse as superconductivity, magnetism, and the fractional quantum Hall effect. A central challenge of contemporary condensed matter research is to achieve a full understanding of these electronic states of matter. If we can explain why these new states appear, and how we can potentially control them, we hold the keys to unlocking future technologies. Our research has a particular emphasis on high temperature superconductivity, and other strongly correlated electron systems, particularly those tuned to a quantum critical point. Experiments are conducted in high magnetic fields, at low temperatures and high pressures using a diverse range of experimental probes, including neutrons and X-rays at international facilities. Another important focus of our research is understanding complex structures and their formation. Here, we use state-of-the-art super-resolution microscopy to study jamming and glass formation in colloidal systems, and computer modelling from molecular to mesoscopic, is also a vital part of the research. Other topics of interest include ice nucleation and electron transport in organic molecules.
Quantum Engineering Technologies
In principle, quantum technologies can perform certain tasks that are forever beyond the capabilities of classical machines, such as factoring large numbers or simulating the dynamics of quantum systems. The theme explores fundamental aspects of quantum mechanics, as well as work towards future photonic quantum technologies, by generating, manipulating and measuring single photons and probing the quantum systems that emit these photons. Students who join the research group typically work in one of three key areas of research:
- Quantum computing
- Quantum communications
- Quantum sensing and metrology
Students can explore a mix of theory and experimentation to devise and demonstrate new protocols for quantum information processing, including quantum simulations, quantum computing and quantum key distribution.
The Particle Physics theme is at the forefront of the data analysis and upgrade of the Compact Muon Solenoid (CMS) and Large Hadron Collider beauty (LHCb) experiments at CERN's LHC. Within CMS the focus is on the search for Supersymmetry and Dark Matter (DM), as well as studying properties of the top quark. Within LHCb the focus is on pioneering new methods to measure CP violation, the asymmetry between matter and antimatter, and studying rare decays of beauty hadrons in order to discover new particles and forces. The theme is also involved in future neutrino experiments such as DUNE, and direct DM detection experiments such as LZ. Furthermore, the theme is involved in developing novel detector technologies and systems, including applications outside particle physics, such as homeland security and medical imaging. Bristol PhD students will usually join one of the experiments and undertake physics analysis as their main activity, and will also be involved in some aspect of the detector operation. Students can also work on new particle detector techniques using CVD diamond, novel integrated detectors, or other future experiments that the theme is actively involved in.
Theory of Condensed Matter and Quantum Information
Theory is an essential complement to experimental physics, guiding and interpreting real world results. Bristol has a distinguished history in theoretical physics, including the discovery of the Aharonov-Bohm effect in 1959 and the geometric or Berry phase in 1983. In soft condensed matter we apply methods from algebraic and geometric topology to study solitons, topological defects and other structures in liquid crystals. Furthermore, we are interested in novel computational techniques applied to topological phase transitions and machine-learning methods applied to problems in statistical physics. Other condensed matter research is concerned with unconventional and novel phases in the spin, charge, and superconducting order of complex materials. In particular, we predict experimental observables, such as thermodynamic and transport properties induced by symmetry-breaking transitions, as well as the electronic signatures of topology in condensed matter systems. Our quantum information research focuses on fundamental aspects, such as paradoxes and nonlocality, as well as understanding why quantum mechanics – which is seemingly counterintuitive – is how it is. We are also interested in the foundations of statistical mechanics and thermodynamics.
A PhD in Physics is an essential qualification for a career as a research physicist, whether in industry, academia or elsewhere. It is valued by employers looking for initiative, numeracy and an ability to plan strategically. Our graduates have the potential to work in a variety of fields, from finance to high-technology start-ups. Please see the School of Physics website for case studies from recent graduates.
Professor Mark Birkinshaw, (William P. Coldrick Professor of Cosmology and Astrophysics)
Professor Malcolm Bremer, (Professor)
Dr Zoë Leinhardt, (Lecturer)
Dr Ben Maughan, (Senior Lecturer)
Professor Steven Phillipps, (Professor)
Professor Diana Worrall, (Professor)
Dr Andrew Young, (Senior Lecturer)
Materials and Devices
Dr Dong (Lilly) Liu, (Lecturer)
Dr Massimo Antognozzi, (Senior Lecturer)
Dr John Day, (Research Fellow)
Professor Peter Flewitt, (Visiting Professor in Interface Analysis Centre (URC))
Dr Neil Fox, (Reader)
Dr Henkjan Gersen, (Senior Lecturer)
Dr Peter Heard, (Research Fellow)
Professor Martin Kuball, (Professor)
Dr Tomas Martin, (Lecturer)
Dr Terry McMaster, (Reader)
Dr Andrei Sarua, (Senior Lecturer)
Professor Tom Scott, (Professor)
Dr Ross Springell, (Lecturer)
Dr Natasa Vasiljevic, (Senior Lecturer)
Dr Jim Brooke, (Lecturer)
Dr Henning Flächer, (Reader)
Professor Joel Goldstein, (Professor)
Dr Helen Heath, (Reader)
Dr Konstantinos Petridis, (Lecturer)
Professor Jonas Rademacker, (Professor)
Dr Jaap Velthuis, (Reader)
Quantum and Complex Matter
Dr Adrian Barnes, (Reader)
Dr Chris Bell, (Senior Lecturer)
Professor Antony Carrington, (Professor)
Professor Stephen Dugdale, (Professor)
Dr Sven Friedemann, (Lecturer)
Professor Stephen Hayden, (Professor)
Dr Jude Laverock, (Graduate Teaching Fellow)
Professor Paddy Royall, (Professor)
Professor Walther Schwarzacher, (Professor)
Quantum Engineering Technologies
Dr Jorge Barreto, (Lecturer)
Dr Anthony Laing, (Lecturer)
Dr Jonathan Matthews, (Senior Lecturer)
Dr Dara McCutcheon, (Lecturer)
Professor Ruth Oulton, (Professor)
Dr Dondu Sahin, (Lecturer in Quantum Engineering)
Dr Peter Turner, (Lecturer)
Theory of Condensed Matter and Quantum Information
Professor James Annett, (Professor)
Dr Stephen Clark, (Senior Lecturer)
Dr Martin Gradhand, (Lecturer)
Dr Simon Hanna, (Reader)
Dr Thomas Machon, (Lecturer)
Professor Sandu Popsecu, FRS, (Professor)
Dr Tony Short, (Senior Lecturer)
Dr Paul Skrzypczyk, (Royal Society University Research Fellow and Lecturer)
Professor Nigel Wilding, (Professor)
We welcome applications at any time of year; early application is advised.
Find out more about becoming a student at Bristol, applying for a visa and the support we offer to international students.
REF 2014 results
- 23% of research is world-leading (4*)
- 62% of research is internationally excellent (3*)
- 15% of research is recognised internationally (2*)
- 0% of research is recognised nationally (1*)
Results are from the most recent UK-wide assessment of research quality, conducted by HEFCE. More about REF 2014 results.
The Bristol Doctoral College facilitates and supports doctoral training and researcher development across the University.
Get in touch
Professor Walther Schwarzacher Director of the Graduate School Phone: +44 (0) 117 928 8735 Email: email@example.com
Briony Spraggon Postgraduate Student Administrator Phone: +44 (0) 117 928 8735 Email: firstname.lastname@example.org
HH Wills Physics Laboratory
University of Bristol
Bristol BS8 1TL http://www.bristol.ac.uk/physics