or
Continue with FacebookLooking to list your PhD opportunities? Log in here.
About the Project
The past four decades of science have witnessed how chemists have learnt from nature, in part by trial and error as well as elegant design, to understand and master the use of weak non-covalent interactions and self-assembly processes in synthetic systems to realise complex multi-component assemblies that exhibit attractive functionalities. The incorporation of molecular recognition units within polymers has afforded a new class of materials – supramolecular polymers – that, on account of weak reversible non-covalent interactions within their assemblies, are dynamic in nature. The Hayes group have discovered several supramolecular polymer systems that are healable in nature[1-4] – when damaged their physical properties can be recovered by application of an appropriate stimulus such as heat or light. Notably. supramolecular polyurethanes have been generated that heal at body temperature[5] – such materials offer great potential in the treatment of wounds or burns. This project targets the discovery of healable supramolecular polymer networks for use in biomedical devices. The project will provide excellent training in the field of polymeric materials – it will involve organic and polymer synthesis, characterisation of the new materials (using techniques such as NMR, IR, UV spectroscopy, mass spectrometry and thermal analysis (DSC, TGA) in the University’s Chemical Analysis Facility) plus GPC analysis (available in the Hayes group research laboratory) and physical assessment of the polymeric materials via rheology and tensiometry (these instruments are available in the Hayes research laboratory). In addition to gaining invaluable scientific technical skills, this project will also develop the ability of the postgraduate student to conduct independent research by providing training on the use of databases (such as Web of Knowledge, Scifinder Scholar, Reaxys), presentation skills and writing reports. By the end of the PhD training, the student will be able to design and execute reactions, interpret complex analytical datasets, and summarise this information in a variety of formats (such as in presentations at group meetings or international conferences or in peer-reviewed publications).
References
References
[1] A Self-Repairing, Supramolecular Polymer System: Healability as a Consequence of Donor-Acceptor pi-pi-Stacking Interactions, S Burattini, H M Colquhoun, J D. Fox, D Friedmann, B W. Greenland, P J F Harris, W Hayes, M E Mackay and S J Rowan, Chem. Commun., 2009, 6717-6719.
[2] A healable supramolecular polymer blend based on aromatic pi-pi stacking and hydrogen bonding interactions, S Burattini, B W Greenland, D Hermida Merino, W Weng, J Seppala, H M. Colquhoun, W Hayes, M E Mackay, I W Hamley, S J Rowan, J. Am. Chem. Soc., 2010, 132, 12051-12058.
[3] Nitroarylurea-terminated supramolecular polymers that exhibit facile thermal repair and aqueous swelling-induced sealing of defects, B C Baker, I M German, A M Chippindale, C E A McEwan, G C Stevens, H M Colquhoun and W Hayes, Polymer, 2018, 140, 1-9.
[4] A thermoreversible supramolecular polyurethane with excellent healing ability at 45 degrees C, A Feula, A Pethybridge, I Giannakopoulos, X Tang, A Chippindale, C R Siviour, C P Buckley, I W Hamley and W Hayes, Macromolecules, 2015, 48, 6132-6141.
[5] An adhesive elastomeric supramolecular polyurethane healable at body temperature, A Feula, X Tang, I Giannakopoulos, A M Chippindale, I W Hamley, F Greco, C P Buckley, C R Siviour and W Hayes, Chem. Sci., 2016, 7, 4291-4300.
[1] A Self-Repairing, Supramolecular Polymer System: Healability as a Consequence of Donor-Acceptor pi-pi-Stacking Interactions, S Burattini, H M Colquhoun, J D. Fox, D Friedmann, B W. Greenland, P J F Harris, W Hayes, M E Mackay and S J Rowan, Chem. Commun., 2009, 6717-6719.
[2] A healable supramolecular polymer blend based on aromatic pi-pi stacking and hydrogen bonding interactions, S Burattini, B W Greenland, D Hermida Merino, W Weng, J Seppala, H M. Colquhoun, W Hayes, M E Mackay, I W Hamley, S J Rowan, J. Am. Chem. Soc., 2010, 132, 12051-12058.
[3] Nitroarylurea-terminated supramolecular polymers that exhibit facile thermal repair and aqueous swelling-induced sealing of defects, B C Baker, I M German, A M Chippindale, C E A McEwan, G C Stevens, H M Colquhoun and W Hayes, Polymer, 2018, 140, 1-9.
[4] A thermoreversible supramolecular polyurethane with excellent healing ability at 45 degrees C, A Feula, A Pethybridge, I Giannakopoulos, X Tang, A Chippindale, C R Siviour, C P Buckley, I W Hamley and W Hayes, Macromolecules, 2015, 48, 6132-6141.
[5] An adhesive elastomeric supramolecular polyurethane healable at body temperature, A Feula, X Tang, I Giannakopoulos, A M Chippindale, I W Hamley, F Greco, C P Buckley, C R Siviour and W Hayes, Chem. Sci., 2016, 7, 4291-4300.
Register your interest for this project
The university will respond to you directly. You will have a FindAPhD account to view your sent enquiries and receive email alerts with new PhD opportunities and guidance to help you choose the right programme.
It looks like you alredy have a FindAPhD Account
Log in to save time sending your enquiry and view previously sent enquiries
* required field
The information you submit to University of Reading will only be used by them or their data partners to deal with your enquiry, according to their privacy notice. For more information on how we use and store your data, please read our privacy statement.
Where will I study?
Search suggestions
Based on your current searches we recommend the following search filters.
Check out our other PhDs in Reading, United Kingdom
Start a New search with our database of over 4,000 PhDs
PhD suggestions
Based on your current search criteria we thought you might be interested in these.
Polymer Materials to Store Biologics at Room Temperature
The University of Manchester
Unusual properties of New Inorganic Framework Materials
University of Reading
Nanostructured materials for energy applications and sensing.
University of Reading