This PhD project at Imperial College London focuses on the in-operando detection and quantification of reactive intermediates in electrolysers and fuel cells. The research aims to advance understanding of electrocatalysis and the formation of reactive species during the operation of these devices, which is crucial for addressing degradation processes that limit their lifespan. Two positions are available: one involves testing electrocatalysts and recombination catalysts in aqueous electrochemical environments using ultramicroelectrode and floating electrode techniques; the other centers on developing in-operando approaches to measure the formation of reactive species within fuel cells and electrolysers under real operating conditions.

Both positions will require experimental work on electrocatalysis, optimizing conditions such as reactant concentration, temperature, and pH. Candidates will also develop and utilize microkinetic electrochemical models to extract kinetic parameters, which will be integrated into three-dimensional multiphysics simulations using software like Comsol. The project is ideal for candidates with backgrounds in chemistry, physics, chemical engineering, or related fields, especially those interested in electrochemical kinetics, instrumentation development, and simulation. Prior experience with electrochemical systems (electrolysers, fuel cells, batteries) is advantageous.

The successful candidate will primarily work within the Department of Chemistry at Imperial College London and will also spend time at the Johnson Matthey Technical Research Centre in Sonning Common, near Reading. This collaboration offers exposure to both academic and industrial research environments. The application deadline is January 25, 2026. For further details and to request an application pack, contact Professor Anthony Kucernak at [email protected], using 'Imperial-JM Studentship' in the subject line. The application pack includes the application form, relevant papers, details of the appointment process, and information about the research group.

This opportunity is ideal for students seeking to develop expertise in advanced electrochemical techniques, kinetic modeling, and the practical application of research in both academic and industrial settings. Funding details are not specified in the announcement.