Course summary

The information provided on this page was correct at the time of publication (November 2022). For complete and up-to-date information about this course, please visit the relevant University of Oxford course page via www.graduate.ox.ac.uk/ucas. The work of this world-class sub-department is in experimental particle physics, particle astrophysics and accelerator physics. Particle physics is the study of basic constituents of matter and their interactions. This is accomplished either directly with accelerators that create the particles under study or by observing high-energy particles from outer space. The sub-department is one of the largest in the UK and is well equipped to carry out research in a wide range of topics, from the study of new particles produced at high energy accelerators to neutrinos, dark matter and dark energy in the Universe. The sub-department’s experiments are carried out at facilities around the world, in Switzerland, Japan, the USA and Canada. You will spend half the first year on a lecture course in addition to starting your research and, if appropriate, spend your second year on-site at your experiment. Laboratories here in Oxford and experiments at overseas facilities provide access to a high-tech environment and excellent research training, directly applicable to a broad range of fields. The world's biggest accelerator, the Large Hadron Collider (LHC) at CERN, is running and in 2012 the Higgs boson, a particle thought to give mass to all elementary particles, was discovered. The understanding of its properties is one of the main aims of the ATLAS experiment. The Oxford group is also focused on the search of new particles predicted in Supersymmetry and others beyond the Standard Model theories. Elucidation of CP violation, one of the mysteries of particle physics, is the aim of the sub-department’s other LHC experiment, LHCb. Both experiments will require you to obtain and analyse data from the highest-energy machine in the world. The sub-department is also involved in the study of neutrino oscillations and neutrino properties at the T2K experiment in Japan, MicroBooNe & DUNE in the USA, and at the Sudbury Neutrino Observatory (SNO+) in Canada. The sub-department has participated in direct searches for dark matter for many years and studentships are now available associated to the LZ project. Recently it has begun a programme in collaboration with the sub-department of astrophysics to elucidate the nature of dark energy with the Large Synoptic Survey Telescope (LSST). The future of particle physics relies on the development of new instruments for detecting particles and novel ideas in accelerator physics. The sub-department is heavily involved in the development of these areas. It has outstanding facilities to build the new silicon detectors needed for the luminosity upgrade of the LHC and other applications. The sub-department is playing a major role in the ProtoDune experimental program at CERN, which is designed to test and validate the Liquid Argon Time Projection Chamber technologies for the construction of the DUNE Far Detector at the Sanford Underground Research Facility (SURF). Furthermore, through the John Adams Institute, students can engage in a range of projects on accelerators which would be used in high energy physics, nuclear physics, as X-ray sources, and in medical applications.