Funded PhD Studentship: DTC PHYS 56 - Transport and Electro-Optics of Next Generation Semiconductors and Devices for Optoelectronics

Swansea University is a UK top 30 institution for research excellence (Research Excellence Framework 2014), and has been named Welsh University of the Year 2017 by The Times and Sunday Times Good University Guide.

Swansea Science DTC is a community committed to undertaking world-class research that has a positive impact globally and we have a fully-funded PhD scholarship for 2017/2018 entry.

Our state-of-the-art facilities include: a low-energy positron beam with dedicated instrumentation for the study of positronium, a number of continuous-wave and pulsed laser systems, and scanning tunnelling, near-field optical and Raman microscopes. High-performance computing resources are available via clusters and dedicated supercomputers.

In the 2014 Research Excellence Framework (REF), over 80% of our Physics’ research outputs were judged to be worldleading or internationally excellent. Research is equally split between experimental and theoretical physics, and is funded via the UK Research Councils (STFC and EPSRC), the Royal Society, the Leverhulme Trust and the European Union.

In experimental physics, we lead the ALPHA collaboration, based at CERN, whose goal is to create, trap and manipulate anti-hydrogen. Results of the ALPHA collaboration are regularly published in Nature and featured on the BBC, CNN and other media. In 2011 the American Physical Society awarded the John Dawson Award for Excellence in Plasma Physics Research to this group. In the Atomic, Molecular and Quantum Physics Group, we also carry out research on ultra-cold atoms, optomechanical systems, ultra-fast lasers, nanotechnology, quantum control with applications in medical imaging, as well as theoretical quantum computation and simulation.

Research in the Theoretical Particle Physics group is focused on all aspects of particle physics, from collider physics phenomenology and the Higgs boson to string theory, black holes and theoretical cosmology. The Lattice QCD group studies the strong interaction under extreme conditions and physics beyond the Standard Model, for which it has ample access to high-performance computing resources in the UK and in Europe.

Description:

The physics of traditional inorganic semiconductors such as silicon has been well established and arguably underpinned the electronic revolution of the past 50 years. New semiconductors based upon low embedded energy materials are emerging and moving forward into applications – such materials include organic semiconductors, quantum dots and organohalide perovskites. The physics of these semiconductors is very different to their more traditional counterparts, and still not fully understood. This project involves the study of a range of next generation semiconductors, specifically focussing on electro-optical properties of critical importance to a new applications in optoelectronics such as solar energy harvesting and photodetection. The project outcomes will feed more applied work in delivering new technology as part of the comprehensive Ser Cymru program on Sustainable Advanced Materials – a cross university endeavour in collaboration with the College of Engineering and SPECIFIC at Swansea University.