- Opens: Tuesday 1 August 2017
- Number of places: 1
OverviewThis project involves different microscopic techniques to investigate semiconductor heterostructures and light-emitting diode devices, performed on our suite of scanning electron microscopes, providing information on material properties at length scales ranging from nanometres to centimetres.
BSc (Hons) 2:1 or equivalent degree in physics
Self-Funded PhD Students Only
The Semiconductor Spectroscopy group is within the Nanoscience division at Strathclyde University and investigates a wide range of light emitting semiconductor materials using optical and electron-beam techniques. Light emitting devices based on Gallium Nitride (GaN) and related materials are a particular speciality (see http://ssd.phys.strath.ac.uk/index.php/Main_Page). We are partners in a number of major projects, including the “Lighting the Future” programme involving Cambridge, Manchester, Bath and Strathclyde Universities.
Over recent years we have developing ways to combine a number of different microscopic techniques to investigate semiconductor heterostructures and light-emitting diode devices. This project involves experiments that will be performed on our suite of scanning electron microscopes, providing information on the materials properties at length scales ranging from nanometres to centimetres. Optical information is provided by spatially-resolved cathodoluminescence (CL) [Ref. 1,2], electroluminescence (EL) and photoluminescence (PL) [Ref. 3]. Compositional information can be collected simultaneously with the CL, using X-ray microanalysis [Ref. 4], and details of conductivity and defects can be collected simultaneously with the EL, using electron-beam induced current (EBIC) data. Work with colleagues in the same group (Dr. Trager-Cowan et al.) brings in electron back-scattered diffraction and electron channelling data, providing information of structural properties such as defects and strain [Ref 5].
The combination of these various techniques, with their high spatial resolution, will allow a fuller understanding and optimisation of the properties of the materials and devices. The ability to apply them simultaneously, or in rapid succession, on exactly the same microscopic region of the samples is new and distinctive. The project will involve work to further extend the power of these techniques and their combination. Structures under study will include Indium Gallium Nitride based quantum wells and LEDs, as being developed for highly efficient solid state lighting and other applications.
J. Bruckbauer et al. Probing light emission from quantum wells within a single nanorod, Nanotechnology 6 365704 (2013)
2. P.R. Edwards and R.W. Martin, Cathodoluminescence nano-characterisation of semiconductors, Semiconductor Science and Technology 26 064005 (2011)
3. S. Schulz et al. Composition-Dependent Band Gap and Band-Edge Bowing in AlInN: A Combined Theoretical and Experimental Study, Applied Physics Express 24 121001 (2013)
4. E. Taylor et al., Composition and luminescence studies of InGaN epilayers grown at different hydrogen flow rates, Semiconductor Science and Technology 28 065011 (2013)
5. G. Naresh-Kumar et al. Coincident Electron Channeling and Cathodoluminescence Studies of Threading Dislocations in GaN, Microscopy and Microanalysis 20 55-60 (2014)
Informal enquiries should be made to the supervisor Prof Robert Martin.