Engineering Functional Materials for Catalytic Smart Microreactors
Lead Research Organisation:
Durham University
Department Name: Chemistry
Abstract
There has been tremendous recent progress in manufacturing very small chemical reactors with channels of the order of micrometres in size. These microreactors allow rapid evaluation of new chemical reactions compared with larger units. The current methods of manufacturing of such reactors are based on expensive and polluting electronics manufacturing techniques. This project will develop faster, cheaper and multifunctional devices with much wider range of potential application. This project involves combining new fabrication methods with recently developed catalysts to provide novel and efficient microreactors. It is a blend of materials science, engineering and chemistry involving mechanical and materials engineers (Liverpool), chemists and surface scientists (Durham) and polymer and organic chemists and chemical engineers (Bath). The complementary expertise of these groups is vital to the success of the programme.The Liverpool group in the first stage of the project will use their experience in Selective Laser Melting (SLM) and Digital Light Processing (DLP) to fabricate novel reactors containing channels < 100 microns in size for reactant and heat exchange fluids in a single unit. These will be evaluated as potential industrial reactors using novel catalysts developed at Bath involving magnetic nanoparticles. In the second stage, the reactant channels will be functionalised using plasma techniques at Durham and converted to catalytically active species using chemistry developed at Bath. A series of test reactions will be performed and the performance analysed by a number of methods. These will require the development of in-situ methods, in order to optimise the design of the reactors and to illustrate the potential benefits to the materials, chemical and pharmaceutical industries. The end result will be a multifunctional reactor with integrated analytics optimised for selected chemical reactions of immediate relevance to the fine chemicals industries.
People |
ORCID iD |
| Jas Pal Badyal (Principal Investigator) |
| Description | Durham's contribution towards this collaborative project was the plasmachemical functionalisation of microreactor walls supplied by Liverpool University with linker groups to then be passed onto Bath University for the immobilization of catalytically active species. The group at Liverpool prepared different internal diameter porous structures using Rapid Manufacturing Technologies (namely Selective Laser Melting (SLM) and Digital Light Processing (DLP)). These included 20 mm plastic tubes with various internal diameters (30 - 1000 microns). They were exposed to a variety of electrical discharges containing glycidyl methacrylate precursor (this monomer provides epoxide groups for subsbequent linkage to catalytic moieties). The chemical nature of the deposited nanolayers was verfied using X-ray photoelectron spectroscopy (XPS), infrared spectroscopy, ellipsometry, and contact angle analysis. Penetration of the plasma throughout each plastic tube internal was proven by reacting the epoxide centres with fluorescent dye and observation using fluorescence microscopy. The presence of fluorescent signal throughout to the central regions of the tubes indicated plasma deposition successfully occurs within their interiors. The developed plasmachemical surface functionalisation approach was then translated to metallic porous structures (metal strips and blocks) prepared by Liverpool University using Selective Laser Melting (SLM), and the coated samples were then submitted to Bath University for catalyst immobilization studies. |
| Exploitation Route | The fundamental understanding gained during the EPSRC catalytic microreactor project regarding the penetration of electrical discharge species into small apertures is being extended to applications for porous ceramic materials as part of follow-on support (£160,449) for an international collaboration awarded to Durham for a project entitled 'Interface Science and Engineering' by the UK-India Education and Research Initiative (UKIERI). |
| Sectors | Chemicals |
| Description | Interface Science and Engineering |
| Amount | £160,449 (GBP) |
| Funding ID | IND/CONT/06-07/186E |
| Organisation | UK-India Education and Research Initiative (UKIERI) |
| Sector | Academic/University |
| Country | United Kingdom |
| Start | 10/2007 |
| End | 06/2011 |
| Description | MCP Equipment |
| Organisation | MCP Equipment |
| Country | United Kingdom |
| Sector | Private |
| Start Year | 2007 |