The flexolighting programme is focussed on research and innovations on materials, processes and device technology for OLED lighting with the intention of building a supply chain within Europe. The aim is to realise OLED devices over a large area/surface with high brightness, high uniformity and long life time. A demonstrator will be built and delivered at the end of the project. The main targets are (i). Cost of the lighting panels should be less than Euro 1 per 100 lumens. (II). high luminous efficiency, in excess of 100 lm/W with improved out-coupling efficiency. (ii). white light life-time of at least 1000 hours at 97% of the original luminance of 5000 cdm-2.(iii). The materials and the devices therefrom will allow for differential aging of the colours, thus maintaining the same colour co-ordinates and CRI over its use. (iv). Attention will be paid to recyclability and environmental impact of the materials and the OLED lighting systems. Flexolighting project will also ensure European industrial leadership in lighting. The introduction of OLED Lighting technology is held back by the current cost of the systems, life-time and poor uniformity of luminance on large area panels. The programme aims to combine existing state of the art OLED materials technology (Thermally activated fluorescent materials (TADF) and phosphorescent emitters and world class transport materials) with new developments in processing technologies (Organic Vapour Phase Deposition (OVPD) and printing technologies) to develop new next of generation low cost OLED lighting systems to move forward to scale up and full scale production on novel planarized flexible steel substrates with cost effective conformal encapsulation method. The transparent top contacts made of thin metallic films, conducting polymers or graphene monolayer with metal tracks to reduce the series resistance will be employed in inverted top emitting OLED structures to deliver 100 lumens per Euro.

Mankind faces great challenges in providing sufficient supplies of renewable energy, in protecting our environment, and in developing benign processes for the chemical and pharmaceutical industries. These urgent problems can only be solved by applying the best available technology, but this requires a solid foundation of fundamental knowledge created through a multidisciplinary yet focussed approach. Catalysis is an essential enabling technology because it holds the key to solving many of these problems. CASTech aims to build on the science and engineering advances developed in previous collaborative programmes involving the main participants. Specifically, new core competencies for the investigation of reactions in multiphase systems will be developed. These will include MR imaging techniques (University of Cambridge, UCam); computational fluid dynamics (UCam); spectroscopic methods (QUB); SSITKA (QUB); flow visualisation and particle tracking (PEPT) (University of Birmingham, UBir); theoretical calculations (University of Virginia, UVa; QUB) for liquid phase processes. An enhanced time resolution fast transient and operando spectroscopy capability will be developed for investigating the mechanisms and the nature of the active sites in heterogeneous catalytic gas phase reactions (QUB). These core competencies will be applied to investigate the activation of saturated alkanes, initially building on our recent success in oxidative cracking of longer chain alkanes.We propose to develop our experimental and modelling capabilities with the objective of providing quantitative data on how to enhance the performance of a catalytic system by understanding and controlling the interaction between the solvent(s), the substrates and the catalyst surface. We aim to be able to describe the structure of liquids in catalytic systems at multiscale from the external (bulk) liquid phase to inside the porous structure of the catalyst and at the catalyst surface. The research will integrate new experimental probes and complementary theoretical approaches to help us understand liquid structures and we will use this information in collaboration with our industrial partners to address specific technical challenges.Bio-polymeric materials, e.g. cellulose and lignin, have the potential to provide functionalised building blocks for both existing and novel chemical products. Our ultimate aim is to provide novel and economically viable processes for the conversion of lignin into high value-added products. However, by starting with the conversion of lignosulphonates into vanillin and other higher value chemicals we will develop not only new processes but also the core competencies required to work with more complex fluids.Biogas (CH4 + CO2) can be produced from many different renewable sources but capturing and storing the energy is difficult on a small distributed scale. We propose to investigate a new, economic, down-sized engineering approach to the conversion of methane to dimethylether. This will be achieved by reducing the number of unit operations and developing new catalysts capable of performing under the more extreme temperature conditions that will be required to make the process economic.The drive to use catalysts for cleaner more sustainable chemistry needs also to address the inherently polluting and unsustainable process of catalyst manufacture itself. We will investigate the sustainable production of supported catalysts using electrochemical deposition of the metal. This method bypasses several conventional steps and would generate very little waste. In all these Grand Challenges there will be close collaboration between all the academic and industrial groups.

Abstracts are not currently available in GtR for all funded research. This is normally because the abstract was not required at the time of proposal submission, but may be because it included sensitive information such as personal details.