Patchy colloidosomes at interfaces: correlation of particle surface heterogeneity, wettability, and chemical activity at the nanoscale. The surfaces of natural mineral particles are made up of spots with such different chemical and physical properties. The complexity makes it hard to predict their behaviour. This project will provide insights into how the 'patchy' nature of particle surfaces affects their behaviour in processes such as flotation separation and bio-fuel production.
Closing the data gap: High throughput screening of nanoparticle toxicity. The nanotechnology sector is experiencing an exponential growth period with over 100 products containing manufactured nanoparticles entering the market every year. Ensuring growth of the sector needs to be balanced against the imperative of protecting both human and environmental safety. This project aims to develop new methodological and conceptual avenues to close the gap between innovation in nanotechnology and risk ass ....Closing the data gap: High throughput screening of nanoparticle toxicity. The nanotechnology sector is experiencing an exponential growth period with over 100 products containing manufactured nanoparticles entering the market every year. Ensuring growth of the sector needs to be balanced against the imperative of protecting both human and environmental safety. This project aims to develop new methodological and conceptual avenues to close the gap between innovation in nanotechnology and risk assessment. This is intended to be achieved by developing and validating high-throughput in vitro toxicity screening platforms for manufactured nanoparticles. The approach is based on advanced lab-on-a-chip microfluidic technologies. The predictive power of the platform will be refined and optimised via ex-vivo and in-vivo models.Read moreRead less
Controlling nano-carbon complexity and function. The project aims to develop versatile continuous flow thin film microfluidic device technology incorporating different external fields, including innovative magnetic or electric fields coupled with pulsed lasers, for gaining access to novel nano-carbon material for which current methods are ineffective or of limited utility. The technology will allow exquisite control, with real time monitoring, on reforming of carbon into functional material with ....Controlling nano-carbon complexity and function. The project aims to develop versatile continuous flow thin film microfluidic device technology incorporating different external fields, including innovative magnetic or electric fields coupled with pulsed lasers, for gaining access to novel nano-carbon material for which current methods are ineffective or of limited utility. The technology will allow exquisite control, with real time monitoring, on reforming of carbon into functional material with tunable properties, along with the self assembly of nano-carbon, and fabricating composites of nano-carbon material. Understanding their fundamental properties including photoluminescence will be targeted, for leveraging the properties in applications to generate new processes and products.
Read moreRead less