Postgraduate combined research and teaching degree programme Biomaterials MRes:
The programme comprises one major research project in Biomaterials, which can be based in the University or in industry, plus six taught modules, five compulsory and one optional.
It is open to those with an upper second-class Honours degree in Science, Health Science or Engineering, and can be taken on a full- or part-time basis.
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This programme comprises one major research project in Biomaterials, which can be based in the University or in industry, plus six taught modules, five compulsory and one optional. It is open to those with an upper second-class Honours degree in Science, Health Science or Engineering, and can be taken on a full- or part-time basis.
We recommend that you start the course at the beginning of the academic year. However, if your background is in Materials Science, then you may start at any time of the year.
The quality of the research work in the Department of Metallurgy and Materials has been confirmed by our outstanding performance in successive Research Assessment Exercises.
We are justly proud of this international reputation and are keen to maintain it by encouraging high quality students from materials, physics, chemistry, life sciences or engineering backgrounds to apply to undertake research with us.
We are prepared to help in finding financial support, if needed. If you are interested in coming to do research with us, or with the Interdisciplinary Research Centre (IRC) in Materials Processing, write directly to me or to the contacts given on our website. I look forward to hearing from you.
Professor Paul Bowen, Head, Metallurgy and Materials
Metallurgy and Materials and the IRC in Materials Processing together make up the largest centre for materials research in the UK. Our Research School comprises more than 20 full-time academic staff in addition to 30 honorary and visiting staff, 30 research fellows and close to 150 postgraduate students.
Our diverse research portfolio ranges from fundamental aspects of materials science to practical high performance engineering applications. Research is funded from a wide range of sources including the UK research councils, the EU and a cross-section of UK and overseas industry. Our research income is around ?4 million per annum.
Most of our research projects involve active collaboration with industrial partners.
The five compulsory modules are:
- Introduction to Materials*
- Materials Characterisation
- Effective Project Management
- Presentation and Communication Skills/Team Skills Development
You may choose one (or two*) options from:
- Degradation of Materials in the Body
- Polymer Science and Soft Matter
- Tissue Engineering
*If you have a background in Materials Science, you will take an additional option in place of Introduction to Materials.
Please note: The modules listed on the website for this programme are regularly reviewed to keep them up-to-date, which may require changes to module content. Also, key members of staff may leave the University and this necessitates a review of the modules that are offered. Where the module is no longer available we will let you know as soon as we can and help you make other choices.
Tuition Fees 2016 academic year:
- £4,121 FT UK/EU students
- £2,061 PT UK/EU students
- £17,910 International students
Learn more about fees and funding.
Scholarships and studentships
Scholarships may be available. International students can often gain funding through overseas research scholarships, Commonwealth scholarships or their home government.
For further information contact the School directly or email email@example.com
An upper second-class Honours degree or equivalent in Science, Health Sciences or Engineering
Learn more about entry requirements
We accept a range of qualifications from different countries – learn more about international entry requirements
Standard English language requirements apply
Learn more about applying
When clicking on the Apply Now button you will be directed to an application specifically designed for the programme you wish to apply for where you will create an account with the University application system and submit your application and supporting documents online. Further information regarding how to apply online can be found on the How to apply pages
Our research facilities for materials preparation range from vacuum melting and casting for special alloys, through crystal growth equipment for rare-earth and very reactive alloys to melt-spinning facilities for the production of rapidly cooled alloys, atomizers to make metal powders and laser ablation equipment for the production of multilayer and superconducting materials.
Surface engineering facilities allow plasma nitriding, boriding, carburising and other surface treatments to be carried out on a range of alloys under controlled conditions, and we have recently installed plasma-spray equipment to produce coatings. There are polymer-processing laboratories and the IRC possesses a large plasma-melting furnace, HIP equipment, direct laser fabrication, a laboratory for the hydrothermal synthesis and colloidal processing of ceramics, and the ?8 million Net Shape Manufacturing Laboratory.
The physical techniques laboratory contains a range of equipment for processes including VSM, dilatometry, differential scanning calorimetry, electrical resistivity and density measurements. The world-class mechanical testing laboratories consist of approximately 30 facilities for fracture and fatigue studies over the temperature range of -196 to 1,500?C, and are accredited by Rolls-Royce for the acquisition and interpretation of data.
Seven creep machines from Nuclear Electric form the basis of a creep-testing laboratory, and thermogravimetric balances, also donated by Nuclear Electric, allow sensitive oxidation measurements to be made at temperatures up to 1,400?C. There is specialised mechanical testing for polymers and foams, at strain rates from creep to impact. X-ray diffraction facilities provide essential back-up to the crystal growth and alloy preparation activities.
Microstructural assessment is well provided for, with a wide range of optical microscopes and quantitative image analysis, and extensive electron microscope facilities. The Electron Microscope Centre provides a service to all schools in the University, as well as to the Midlands region. The five SEMs include
a JEOL 7000F with WDX, EDX and EBSD;
an FEI FEG ESEM with cryo and heating (1500?C) stages.
The TEMs include
a 200 kV FEI Tecnai F20 FEG(S)TEM with PEELS, EDX and HAADF.
A scanning Auger facility with an X-ray photo-electric spectrometer (XPS) is available for a wide range of surface studies and we also have an atomic force microscope.
The new hydrogen technology laboratory has a range of equipment to characterize the properties of materials in hydrogen. This includes two constant pressure Thermogravimetric Analysers, and a volumetric PCT system to measure the uptake and sorption kinetics of hydrogen storage materials.
A recent addition has been the Netzch differential scanning calorimeter (DSC) with simultaneous thermal analysis (STA). Nicolet Magna-IR infrared and Raman spectrometers are being used to study polymer and ceramic-type materials. Other novel analytical equipment in this category include simultaneous DSC and FTIR, DSC and non-contact thermo-mechanical analysis.
The Department has good facilities for the fabrication and characterization of optical fibre sensors including sensor systems for strain, temperature, vibration, acoustic emission and chemical sensing. The autoclave-based processing of advanced fibre reinforced composites is carried out in the Astro-Physics Department.
We have excellent workshop facilities and a large suite of networked PCs, housed in a computing laboratory provided by Corus, which supplements the extensive computer facilities in individual research groups.
Examples of MRes Biomaterials Research Projects
- Bugs into bone: novel nanomaterials for biomedical applications – L. Macaskie,R. Sammons, P. Marquis
- Surface modification of Ni-free biomedical stainless steels – H. Dong
- Biocompatibility and wear properties of surface engineered austenitic stainless steels – H. Dong, R. Sammons
- Comparative studies on the biocompatibility and nano mechanical properties of anatase and rutile titanium dioxides – H. Dong, R. Sammons
- Characterisation of dental resins using simultaneous DSC/FTIR/TMA – G. Fernando, M. Jenkins, W. Palin, P. Marquis
- Improving the corrosion resistance of titanium prosthetic alloys – A. Davenport
- Effect of proteins on the corrosion of implant alloys – A. Davenport
- Structural characterisation of novel fluoride-containing calcium phosphate glasses and glass ceramics – A. Stamboulis
- Degradation studies in polycaprolactone-chitin composites – A. Stamboulis, M. Jenkins
- Characterisation of mixed Ca/Ba apatite glass ceramics – A. Stamboulis
- Laser ablation of apatite stoichiometric ionomer glasses on titanium substrate – A. Stamboulis, A. Davenport, S. Abel
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