Be part of the latest discoveries: from probing what happened an instant after the Big Bang, developing new quantum materials to leading the quest to find gravitational waves and leading experiments to ‘see’ inside the sun and other stars. By studying a PhD with us, you will be applying knowledge to science and engineering to make a positive difference to society, industry and our environment.
Birmingham is home to a vibrant and supportive physics research community. From our strong connections, you will have a range of opportunities to meet other researchers, discuss your work and learn about the cutting-edge projects being carried out by academics within the University and at other institutions.
As well as benefitting from regular colloquia, you’ll have access to an unparalleled support network. All doctoral researchers have a mentor as well as a supervisor and by working in research groups, you will have access to support across the group, including the head of section.
As a doctoral researcher at Birmingham, you’ll have easy access to the materials and facilities you need to conduct world-class research.
Our doctoral researchers have access to excellent facilities. For example, we operate the most flexible research cyclotron in the UK. As part of the ongoing development of our research laboratories we have also recently commissioned a new suite of hot rooms to support in vitro cell radiobiology studies.
We collaborate closely with the University Hospital Birmingham NHS Foundation Trust, which provides extensive irradiation and radiation calibration facilities. We are also home to the Positron Imaging Centre, where positron-emitting radioactive tracers are used in interdisciplinary research involving a number of University groups and industrial sponsors.
Our Nanoscale Physics Research Laboratory - the first centre for nanoscience in the UK - is a world-leading player in nanoscience research with many links to experimental and theoretical groups in Europe and beyond, as well as to high-tech companies. The Nanoscale Science Facility and Centre for Advanced Materials house a suite of powerful new tools to probe the physics and applications of nanoscale structures created in the Lab. Research ranges from atomic manipulation through atomic clusters to new catalysts and biochips. The Laboratory is a key partner in the University's new bio-imaging centre.
In Condensed Matter Physics our facilities can observe macroscopic quantum effects in objects cooled close to absolute zero. Of current interest are nanoscale mechanical resonators interacting with superconducting microwave circuits. Meanwhile, our Cold Atom research facilities are part of an £11 million investment to form the Midlands Ultracold Atom Research Centre and the Midlands Physics Alliance Graduate School with the universities of Nottingham and Warwick.
Our nuclear group is a leading player in experiments that are performed at some of the world’s premier research laboratories such as the Large Hadron Collider at CERN and in-house facilities for the development of new detectors and their associated electronics.
Our particle physics group is making central contributions to the exploration of the new landscape of fundamental physics as revealed at CERN, where we played a major role in the recent discovery of the Higgs boson and for which a Birmingham physicist is the current spokesperson.
Our activities in astrophysics and space research make use of a variety of observatories on the ground and in space, as well as powerful computing facilities, to explore a wide range of topics, including the physics of the Sun, stars (including exoplanets) and galaxies, cosmology, and the study of gravity and gravitational waves. We have a long heritage in the design and manufacture of space instrumentation, and have clean rooms, a state-of-the-art facility for the assembly and testing of space-qualified electronics and an environmental test facility.
Metamaterials are opening up exciting gateways in optical science and technology, making it possible to build ‘invisibility cloaks’, which can shroud objects and render them unobservable; make lenses which can exceed the resolution diffraction limit; and develop materials which nullify and even reverse the tendency of the parts of ultra-small machines to stick together (the so-called ‘Casimir force’).
Molecular Physics has established a unique suite of instrumentation used for the study of electron attachment and ion-molecule processes. This experimental resource is not available anywhere else, and represents a cutting-edge multidisciplinary facility for innovative and distinctive applied and basic research.