Electrical energy storage can contribute to meeting the UK's binding greenhouse emission targets by enabling low carbon transport through electric vehicles (EVs) in the expanding electric automotive industry. However, challenges persist in terms of performance, safety, durability and costs of the energy storage devices such as lithium ion batteries (LIBs). Although there has been research in developing new chemistry and advanced materials that has significantly improved electrical energy storage performance, the structure of the electrodes and LIBs and their manufacturing methods have not been changed since the 1980s. The current manufacturing methods do not allow control over the structures at the electrode and device levels, which leads to restricted ion transport during cycling. The approach of this research is to develop a complete materials-manufacture-characterisation chain for LIBs, solid-state LIBs (SSLIBs) and next generation of batteries. Novel structures at the electrode and device levels will be designed to promote fast directional ion transport, increase energy and power densities, improve safety and cycling performance and reduce costs. New, scalable manufacturing techniques will be developed to realise making the designed structures and reduce interfacial resistance in SSLIBs. Finally, state-of-the-art physical and chemical characterisation techniques including a suite of X-ray photoelectron spectroscopy (XPS), X-ray computed tomography (XCT) and electrochemical testing will be used to understand the underlining charge storage mechanism, interfacial phenomena and how electrochemical performance is influenced by structural changes of the energy storage devices. The results will subsequently be used to guide iterations of the structure design. The fabricated batteries will be packaged into pouch cells and rigorously tested by EV protocols through close collaborations with industry to ensure flexible adaptability to the current industry match to create near-term high impact in industry. The commercialisation strategy is to license developed intellectual property (IP) to material and battery manufacturers.

Cheap, safe and high-energy batteries are required for applications such as the electrification of transport, the large-scale storage of energy from renewable resources and consumer portable devices. Lithium-oxygen and lithium-sulphur batteries are very promising candidates because they have the potential to store more than 5 times higher energy than today's lithium-ion batteries of the same weight and volume. Currently, the performance of lithium-oxygen and lithium-sulphur batteries is limited by several fundamental challenges. This project will develop an experimental-based physical-chemical understanding of the underlying processes and will develop tailored solutions to overcome these problems. Our approach will be to fundamentally change the reaction mechanism in order to boost battery performance. Homogeneous catalysts capable of transferring several electrons will be explored with the aim of eliminating problematic reaction intermediates. This is expected to not only enhance reaction kinetics but also to suppress degradation reactions. Novel electrolytes will be developed which are designed to provide ultrafast charge transport of the homogeneous catalysts. Novel lithium protection approaches will also be explored, which are designed to suppress unwanted reactions on the lithium electrode as well as enhancing the safety of these batteries. In conclusion, this project aims to achieve a step change in rechargeable lithium batteries based on a full mechanistic understanding and tailored innovative approaches.

The ability to store and release energy on demand is essential to an energy future that is based on clean, non-polluting and sustainable renewable energy. This includes both electrical and thermal energy and a large number of technologies are being developed to fulfil this need. Energy storage will become a major industry in our century and will employ hundreds of thousands of people globally. Energy storage will be everywhere - in large scale batteries connected to electrical networks, in homes to store energy generated from solar panels and in cars, replacing petrol engines. In order to meet this challenge and to ensure that UK plays an important role in this industry we will form a Centre of Doctoral Training in to train researchers at the highest level to help form and influence the direction of Energy Storage technologies. Our students will receive training in all aspects of energy but concentrating on the core technologies of electrochemical storage (batteries and supercapacitors), mechanical storage, thermal storage and superconducting magnetic energy storage. They will have the opportunity to interact with industrialists and gain experience in running a grid connected Lithium-ion battery. They will also undertake a major three-year research project allowing them to specialise in the topic of their choice.

Electrical energy storage can contribute to meeting the UK's binding greenhouse emission targets by enabling low carbon transport through electric vehicles (EVs) in the expanding electric automotive industry. However, challenges persist in terms of performance, safety, durability and costs of the energy storage devices such as lithium ion batteries (LIBs). Although there has been research in developing new chemistry and advanced materials that has significantly improved electrical energy storage performance, the structure of the electrodes and LIBs and their manufacturing methods have not been changed since the 1980s. The current manufacturing methods do not allow control over the structures at the electrode and device levels, which leads to restricted ion transport during cycling. The approach of this research is to develop a complete materials-manufacture-characterisation chain for LIBs, solid-state LIBs (SSLIBs) and next generation of batteries. Novel structures at the electrode and device levels will be designed to promote fast directional ion transport, increase energy and power densities, improve safety and cycling performance and reduce costs. New, scalable manufacturing techniques will be developed to realise making the designed structures and reduce interfacial resistance in SSLIBs. Finally, state-of-the-art physical and chemical characterisation techniques including a suite of X-ray photoelectron spectroscopy (XPS), X-ray computed tomography (XCT) and electrochemical testing will be used to understand the underlining charge storage mechanism, interfacial phenomena and how electrochemical performance is influenced by structural changes of the energy storage devices. The results will subsequently be used to guide iterations of the structure design. The fabricated batteries will be packaged into pouch cells and rigorously tested by EV protocols through close collaborations with industry to ensure flexible adaptability to the current industry match to create near-term high impact in industry. The commercialisation strategy is to license developed intellectual property (IP) to material and battery manufacturers.

Carbon anodes for Li-ion batteries (LIBs) are regarded as one limiting factor preventing Li-ion batteries from being a viable option for transport applications (which require higher capacity for extended driving ranges) or grid storage applications (which require long cycle life). Compared to carbon, silicon has a much higher energy density and has been the focus of considerable research effort in recent years, stimulating the formation of high-profile, high-investment university spin-out companies such as Amprius and Nexeon. Silicon is the second most abundant element in the earth's crust and is thus a sustainable battery material candidate from a cost and availability perspective. However, despite its desirable properties for Li-ion batteries, it is also renowned for its drawbacks, namely large volume expansion, pulverisation and continued lithium loss through chemical reactions with the electrolyte (which the lithium ions diffuse in). Such phenomena have hindered the successful widespread uptake of this material in commercial Li-ion batteries, despite the myriad of global research groups working on finding ways to make it viable, e.g. by nano-structuring. Project AMorpheuS presents an alternative way to fabricate Si anodes that does not rely on complex, costly nanostructuring or attempting to control electrode architectures. The approach is simply to deposit from solution using electrodeposition methods and to passivate the amorphous thin films with polymer chemistries that have already been shown to be effective as binders for Si electrodes. A fundamental understanding of the structural and surface properties of these electrodes will be obtained during realistic battery operation so as to identify the optimum Si alloy and polymer chemistry and optimise performance rationally. This project will develop Si electrodes that are not exclusively destined for use in Li-ion systems but can also be reversibly cycled in Na-ion and Li-S batteries. A variety of Si-alloy chemistries will be explored, including Si-Sn alloys, since these show considerable promise as anodes for Na-ion batteries. A goal is to develop the first Si-based Na anode. This flexibility opens up numerous technology transfer opportunities in a variety of emerging battery systems focused on higher energy, sustainable, and safer technologies (e.g. Li-ion, Na-ion and LiS, respectively). The new batteries will be tested in the UK's first full battery prototyping line in a non-commercial environment. Fully understanding what occurs in a battery as it is charged / discharged is complex. The battery is a closed system with constantly changing domains. Central to the success of this project is the application of in-situ characterisation techniques for analysing real-time, dynamic structural and surface changes that occur as Li ions pass back and forth between the anode and cathode (or why they do not). This knowledge will subsequently guide continued improvements in electrode designs. The major techniques proposed to gain a comprehensive understanding of the chemistry occurring in the battery as it is charged/discharged are multinuclear NMR and X-ray computed tomography. These techniques have provided battery researchers with a wealth of vital, real-time insight - especially regarding failure mechanisms in silicon materials. Project AMorpheuS's approach will reduce the need for additional processing of materials in the electrodes, e.g., (i) high surface area carbons (which need energy-intense mixing processes) and (ii) industry-standard binders (which require toxic solvents to enable them to be processed into coatings). This strategy will reduce production time and eliminate toxic chemicals. These improvements will significantly reduce manufacturing cost and increase the UK's energy security.