Chemists have always been in demand worldwide with pharmaceutical and biotechnology industries, fine chemicals, and within research laboratories across the globe. The programme at Aberdeen is accredited by the Royal Society of Chemistry. Aberdeen is noted for Nobel prizes within Chemistry which include the invention of modern chromatography (Synge 1952) and the discovery of a new element - protactinium (Soddy 1921). Teaching at Aberdeen is informed by world class research within food security. Class sizes are kept small to enable you to have strong teaching interaction and support in your studies. You will be taught by many staff in the environment group (TESLA) https://www.abdn.ac.uk/ncs/departments/chemistry/trace-element-speciation-laboratory-111.php and (MBC) https://www.abdn.ac.uk/ncs/departments/chemistry/marine-biodiscovery-centre-112.php
The programme focuses on specialised modern analytical methodology. The range of industries or institutes where these skills are asked for includes the pharmaceutical industry, environmental institutions, research institutes and also the oil & gas industry. There are many new innovations which require chemists with advanced skills to analyse and test new methods of providing health via IOT devices, smart phones and small sensors deployed throughout the body to quickly provide analysis and customised recommendations.
Advanced Analytical Methodologies A and B
Practical Exercise and Professional Skills in Analytical Chemistry
Research Techniques and Professional Skills and Problem Solving Theory and Practice
Research Project in Analytical Chemistry
Research Project in Analytical Chemistry
Find out more detail by visiting the programme web page
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*Please be advised that some programmes have different tuition fees from those listed above and that some programmes also have additional costs.
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Pursuing a research degree at the School of Chemistry could be one of the best experiences of your life.
In addition to gaining research skills, making friends, meeting eminent researchers and being part of the research community, a research degree will help you to develop invaluable transferable skills which you can apply to academic life or a variety of professions outside of academia.
The Chemistry/Biology Interface
This is a broad area, with particular strengths in the areas of protein structure and function, mechanistic enzymology, proteomics, peptide and protein synthesis, protein folding, recombinant and synthetic DNA methodology, biologically targeted synthesis and the application of high throughput and combinatorial approaches. We also focus on biophysical chemistry, the development and application of physicochemical techniques to biological systems. This includes mass spectrometry, advanced spectroscopy and microscopy, as applied to proteins, enzymes, DNA, membranes and biosensors.
Experimental & Theoretical Chemical Physics
This is the fundamental study of molecular properties and processes. Areas of expertise include probing molecular structure in the gas phase, clusters and nanoparticles, the development and application of physicochemical techniques such as mass spectoscropy to molecular systems and the EaStCHEM surface science group, who study complex molecules on surfaces, probing the structure property-relationships employed in heterogeneous catalysis. A major feature is in Silico Scotland, a world-class research computing facility.
This research area encompasses the synthesis and characterisation of organic and inorganic compounds, including those with application in homogeneous catalysis, nanotechnology, coordination chemistry, ligand design and supramolecular chemistry, asymmetric catalysis, heterocyclic chemistry and the development of synthetic methods and strategies leading to the synthesis of biologically important molecules (including drug discovery). The development of innovative synthetic and characterisation methodologies (particularly in structural chemistry) is a key feature, and we specialise in structural chemistry at extremely high pressures.
The EaStCHEM Materials group is one of the largest in the UK. Areas of strength include the design, synthesis and characterisation of functional (for example magnetic, superconducting and electronic) materials; strongly correlated electronic materials, battery and fuel cell materials and devices, porous solids, fundamental and applied electrochemistry polymer microarray technologies and technique development for materials and nanomaterials analysis.
Students attend regular research talks, visiting speaker symposia, an annual residential meeting in the Scottish Highlands, and lecture courses on specialised techniques and safety. Students are encouraged to participate in transferable skills and computing courses, public awareness of science activities, undergraduate teaching and to represent the School at national and international conferences.
Our facilities are among the best in the world, offering an outstanding range of capabilities. You’ll be working in recently refurbished laboratories that meet the highest possible standards, packed with state-of-the-art equipment for both analysis and synthesis.
For NMR in the solution and solid state, we have 10 spectrometers at field strengths from 200-800 MHz; mass spectrometry utilises EI, ESI, APCI, MALDI and FAB instrumentation, including LC and GC interfaces. New combinatorial chemistry laboratories, equipped with a modern fermentation unit, are available. We have excellent facilities for the synthesis and characterisation of bio-molecules, including advanced mass spectrometry and NMR stopped-flow spectrometers, EPR, HPLC, FPLC, AA.
World-class facilities are available for small molecule and macromolecular X-ray diffraction, utilising both single crystal and powder methods. Application of diffraction methods at high pressures is a particular strength, and we enjoy strong links to central facilities for neutron, muon and synchrotron science in the UK and further afield. We are one of the world's leading centres for gas-phase electron diffraction.
Also available are instruments for magnetic and electronic characterisation of materials (SQUID), electron microscopy (SEM, TEM), force-probe microscopy, high-resolution FTRaman and FT-IR, XPS and thermal analysis. We have also recently installed a new 1,000- tonne pressure chamber, to be used for the synthesis of materials at high pressures and temperatures. Fluorescence spectroscopy and microscopy instruments are available within the COSMIC Centre. Dedicated computational infrastructure is available, and we benefit from close links with the Edinburgh Parallel Computing Centre.
These Royal Society of Chemistry accredited courses enable you to develop and further your knowledge of chemistry from our extensive range of modules. You can expand your interests by completing a research project to allow you to match it to your interests and career aspirations.
The MRes Chemistry course is divided into a taught element (60 credit points) and a laboratory-based research project (120 credit points). You will complete the extended research project in one of our highly rated research teams.
The MSc Chemistry course is divided into 60 credit point taught modules and the research project is worth 60 credit points. The course covers a diverse range of topical chemical areas and includes a research lead project. Students can take the MSc Chemistry route with one year full-time study, or alternatively you can also undertake one year full-time study plus a year long work placement for the MSc Chemistry (Professional Practice) route.
Graduates from this course have gone on to work in sectors such as:
Visit us on campus throughout the year, find and register for our next open event on http://www.ntu.ac.uk/pgevents.