The CritCat proposal aims to provide solutions for the substitution of critical metals, especially rare platinum group metals (PGMs), used in heterogeneous and electrochemical catalysis. CritCat will explore the properties of ultra-small transition metal (TM) nanoparticles in order achieve optimal catalytic performance with earth-abundant materials. The emphasis will be on industrially-relevant chemical reactions and emerging energy conversion technologies in which PGMs play an instrumental role, particularly in the context of hydrogen and synthesis gas (syngas) fuels. The CritCat proposal includes all the aspects for rational catalyst design including novel catalyst synthesis, characterization, and performance testing by a range of academic and industry partners together with large-scale computational simulations of the relevant catalysts, substrates and model reactions using the latest computational methods. Particular attention is given to a strong feedback-loop mechanism where theory is an integral part of the experimental work packages. The experimental and theoretical data will be collected (descriptor database) and used for materials screening via machine learning techniques and new algorithms. The goal is to improve size, shape and surface structure control of the tailored nanoparticle catalysts via novel cluster/nanoparticle synthesis techniques that can produce samples of unrivalled quality. The research includes up-scaling of the size-selected catalyst nanoparticle samples up to macroscopic quantities, which will enable them to be included as basic technological components for realistic catalyst systems. The performance of the catalyst prototypes will be demonstrated for selected basic electrochemical reactions relevant to fuel cells and storage of renewable energy. The industrial partners bring their expertise in prototypes development and commercial deployment (TRL 3-4). The project involves cooperation with external research groups in USA and Japan.

The saturation of wireless spectrum access is leading to innovations in areas such as spectrum resource usage. It is widely thought however that the low hanging fruits of innovation for wireless communication are all but exploited with only marginal gains possible. For a real step change towards the coveted 1Tbps wireless transmission, new areas of the spectrum must be utilized. Recent breakthroughs in terahertz systems are overturning the “Terahertz gap” stigma associated with the previously difficult to access spectrum. With the emergence of viable THz communications systems on the horizon, it is crucial to develop a technology roadmap for THz communication for beyond the 5G timeframe. The aim TERAPOD is to investigate and demonstrate the feasability of ultra high bandwidth wireless access networks operating in the Terahertz band. The project will focus on end to end demonstration of the THz wireless link within a Data Centre Proof of Concept deployment, while also investigating other use cases applicable to beyond 5G such as wireless personal area networks, wireless local area networks and high bandwidth broadcasting. The project seeks to bring THz communication a leap closer to industry uptake through leveraging recent advances in THz components, a thorough measurement and characterization study of components and devices, coupled with specification and validation of higher layer communication protocol specification.