Design and synthesis of self-healing polymer systems

The aim of this research was to develop self-healing polymer systems that would be expected to mimic many of the features of a biological system. The proposed self-healing system is based on incorporating microencapsulated a novel healing agent (mixtures of mono- and di-functional monomers) and a catalyst within the epoxy resin matrix. The principle will be that when a crack is formed in the epoxy matrix, the embedded microcapsules will be expected to rupture releasing healing agent into the crack plane. Polymerisation of the healing agent will then be triggered by contact with the embedded catalyst, bonding the crack faces and accomplishing a self-healing process. The project was implemented successfully according to the work plan. All the project objectives and milestones have been successfully achieved within the timescale.

The most important scientific achievement made through this project are outlined below:
- Novel healing agents based on a group of mono- and di-functional monomers, which can be rapidly polymerised in the presence of a catalyst, were prepared and fully characterised.
- The healing agents were successful encapsulated and high quality microcapsules were prepared.
- Epoxy resin plaques containing microcapsules and catalyst were successfully prepared.
- Micro-cracks were initiated in the epoxy resin plaques and the self healing process was monitored by the mechanical testing.
- The mechanical testing of the samples showed that excellent self-healing coefficient ranging from 17 to 44 %. This is the first example of good efficiency of healing auto-reparation of micro-cracks at room temperature with low concentration of catalysts.
- The best example in the literature is claimed to exhibits a self-healing coefficient of maximum 25 % which is inferior to the system we have developed here during this project.
- The project enabled us to establish a novel and superior self-healing system.