As part of the UK Government announcement on advance manufacturing the Faraday Institution, the UK’s flagship institute for electrochemical energy storage research, has announced a £19 million investment in four key battery research projects aimed at delivering beneficial impact for the UK.
The FutureCat project is jointly led by Professor Serena Cussen, University of Sheffield, and Professor Louis Piper, WMG, University of Warwick. The project also comprises research teams at the universities of Cambridge, Birmingham, Imperial College London, Lancaster, and newly joined by Nottingham and Diamond Light Source.
Professor Serena Cussen said “this investment means we continue our development of next generation cathodes for Li-ion batteries which are critical for the future of electric vehicles and our transition to net zero. Our consortium is answering fundamental questions around novel redox processes, designer morphologies and scalable materials production to deliver high performance and lower cost cathode materials of the future”
FutureCat has a focus on high-capacity, high-performance nickel-rich oxide cathodes targeting premium electric vehicle applications and delivering these at scale
FutureCat is targeting step-changes in:
- Understanding novel redox processes as a route to stabilise both high capacity, high performance, nickel rich and emerging cathodes. The project continues its focus on doped and dual-doped lithium nickel oxides (LNO) (both polycrystalline and single crystals), including use of protective coatings. The team will also investigate the use of polyanionic cathodes, use modelling to inform the search for new candidate materials, and research designer electrolytes with the intention of stabilising the interphase layer.
- Scalable designer morphologies. The project will build on its success with doped-LNO in developing reliable, scalable routes to deliver longer lifetime, high-energy/power cathodes through the use of gradient morphologies, co-doped cathodes (with the aim of delivering reversible discharge capacities exceeding 220 mAh/g), single crystal particles and thin coatings.
- Materials delivery: The scale up of the high nickel W-LNO material previously developed by FutureCat is being transferred to the Degradation project for testing in industry-relevant pouch cells. FutureCat will continue to investigate the manufacturing scale-up of other Ni-rich cathode materials, down-selecting promising active materials based on earth-abundant elements. Research includes the use of laser patterning to increase power densities, investigation of cracking as a failure mechanism to determine routes to resilient cathode manufacture, atomic layer deposition of coatings to improve electrode longevity, and optimisation of cycle life through the use of electrically conductive binders.