The performance of materials used for electrochemical energy storage (batteries), or the catalytic conversion of waste products into industrially useful chemicals, is typically defined by reactions occurring at their interface with a liquid or gas environment. As the reaction conditions change so these interfaces change, with often dramatic effects on their structure, chemistry and performance. Understanding the evolution of these interfaces is critical to developing the improved materials needed for a more sustainable economy. However, it is extremely challenging to extract information from these interfaces during operation, due to interference from the bulk phases either side, which scatter most interface-sensitive probes.
The ambition of this project is to pioneer enclosed environmental reaction cells to extend the operation of a range of interface-sensitive characterisation techniques to liquid and high-pressure gas environments, such that the chemical and structural evolution of material interfaces can be resolved under realistic operating conditions. The motivation is to be able to directly explore and hence understand the key processes occurring at material interfaces that underpin sustainable technologies. This will transform our understanding of interfacial processes which will be key to the design of future materials for sustainable energy applications.
The operando characterisation techniques developed in this project will be made widely available to the research community thanks to the relatively low cost of such enclosed cells and their portability across existing characterisation equipment already available at many research institutions. Although battery electrode and catalyst interfaces are the primary focus of this project, these will serve as exemplar cases, with the methodology readily transferable to many other research fields, including materials synthesis, electrocatalysis, and environmental science.
These new capabilities will enable both accelerated screening of new catalyst and electrode materials and a rational approach to their optimisation based on understanding the fundamental origins of their performance. By observing the interfacial behaviour of transition metal oxides across different applications (batteries and catalysis), key insights are expected that will inform the design and discovery of new materials, cycling protocols and reaction conditions, beyond the current trial-and-error approach. For example, operando studies of electrolyte decomposition in Li-ion batteries will aid us in the selection of additives and charging protocols.
The overarching aim of this project is to develop these new characterisation capabilities and demonstrate their importance through the study of materials interfaces relevant to future sustainable technologies. The key objectives are to:
(a) Develop enclosed-cell approaches to extend the operation of a range of complementary interface-sensitive characterisation techniques to liquid and high-pressure gas (up to 10 bar) environments, such that the chemical and structural evolution of representative material interfaces can be resolved under realistic operating conditions.
(b) Develop new deposition pathways for integrating battery electrode and catalyst materials of controlled chemical composition and morphology with the windows used in the enclosed reaction cells
(c) Establish understanding of structure-property relationships for transition metal oxide interfaces used as lithium-ion battery cathodes, and heterogeneous catalysts.
(d) Connect the behaviours observed in lithium-ion battery cathodes with catalysts used for chemical feedstock and liquid fuel synthesis, to identify common trends that are generally applicable to TMO interfaces.
(e) Inform the development of materials solutions to problems such as battery capacity fade and poor catalyst selectivity, and perform operando measurements to validate these solutions.