An electrochemical route to green, decentralised ammonia: Advancing electrolytes and materials for lithium-mediated nitrogen reduction

About this opportunity

As a PhD researcher, you will explore a new sustainable and scalable electrochemical route to ammonia (NH₃) from atmospheric nitrogen, the lithium-mediated nitrogen reduction reaction (Li-NRR) and other earth-abundant metals (M-NRR). Developing skills in electrochemical analysis and electrolyte materials chemistry, you will determine the factors controlling and limiting Li/M-NRR and apply this knowledge to advance the formulation of new and improved materials and conditions to address this critical sustainability challenge.

Ammonia is an essential chemical for fertilisers required for global food security and has potential as a zero-carbon fuel. However, NH₃ production via the Haber Bosch process is one of the largest and most polluting chemical industries, accounting for >2% of human-made CO₂ while being heavily centralised within developed countries. The Li/M-NRR is a room-temperature electrocatalytic reaction that could exploit the growing availability of renewable electricity, be significantly more scalable and, therefore, help to decentralise NH₃ synthesis to improve fertiliser equity and security. Within Li-NRR, the reactive electroplated lithium can break the strong N₂ triple bond, forming Li₃N that reacts with labile protons to form NH₃. However, while Li-NRR and Ca-NRR are the only routes proven conclusively to convert N₂ to NH₃ (Nature, 2019, 570, 504–508, Nat. Mater., 2024, 23, 101–107), there are restrictions to the current understanding of the chemistry and materials limiting reaction stabilities and efficiencies.

As a PhD student, you will join a team working towards the shared goal of advancing Li/M-NRR chemistry by understanding and optimising the underlying reaction mechanisms. This PhD project will work towards this goal by exploring the key electrolyte/material properties, developing new materials to overcome the challenges. First reported in 1930 (Helv. Chim. Acta 1930, 13 (6), 1228-1236.), only recent efforts have demonstrated the potential of Li-NRR for NH₃ production at scale. As such, there is a large material space to explore the electrolyte formulations, substrates, and proton carriers to (1) tune the critical electrolyte/electrode interface, interphases, and surface film properties (J. Am. Chem. Soc, 2025, 147, 33, 29687–29701), (2) control

electrodeposition of reactive group1/2 metals (linking importantly with frontier battery chemistry research), (3) identify structure-property and formulation-property relationships, and (4) develop novel materials/parameters to optimise reaction selectivity and stability needed for green ammonia electrosynthesis.

You will be trained in electrochemical analysis, non-aqueous electrochemistry, air-sensitive chemistry, and spectroscopic characterisation, with opportunities to contribute towards cell/equipment design and development. This will be coupled with a variety of rigorous analytical methods to prove NH₃ is a direct product from N₂ reduction. As part of the wider team, you will have the opportunity to test electrochemical and material hypotheses using advanced operando/in situ spectroelectrochemical and microscopy techniques being developed in the group. Further, evaluation of material discoveries at larger scales will be targeted through collaborations with project partners.

As you explore the key electrolyte/material relationships towards enhancing Li/M-NRR, you will have the opportunity to communicate your findings through publications, as well as at national and international scientific meetings.

Any informal enquiries about the project may be sent to alex.neale@liverpool.ac.uk.

Further reading

1. Nature, 2019, 570, 504–508. (https://www.nature.com/articles/s41586-019-1260-x)
2. Nat. Mater., 2024, 23, 101–107 (https://www.nature.com/articles/s41563-023-01702-1)
3. Helv. Chim. Acta 1930, 13 (6), 1228-1236 (https://onlinelibrary.wiley.com/doi/10.1002/hlca.19300130604)
4. JACS, 2025, 147, 33, 29687–29701 (https://pubs.acs.org/doi/full/10.1021/jacs.5c03389)
5. Nat Energy7, 1217–1224 (2022). (https://www.nature.com/articles/s41560-022-01144-0)

Who is this for?

Candidates will have, or be due to obtain, a 2:1 or higher Master’s Degree or equivalent in Chemistry, Physics, or Materials Science. Exceptional candidates with a First Class Bachelor’s Degree in an appropriate field or significant relevant experience will also be considered. Experience in electrochemistry and analytical chemistry is an advantage.

Funding your PhD

This faculty funded Studentship will cover full tuition fees (for 2026-27 this is £5,238 pa.) and pay a maintenance grant for 3.5 years, at the UKRI standard rates (for 2026-27 this is £21,805 pa.). The Studentship also comes with access to additional funding (2) in the form of a Research Training Support Grant to fund consumables, conference attendance, etc.

We want all of our Staff and Students to feel that Liverpool is an inclusive and welcoming environment that actively celebrates and encourages diversity. We are committed to working with students to make all reasonable project adaptations including supporting those with caring responsibilities, disabilities or other personal circumstances. For example, If you have a disability you may be entitled to a Disabled Students Allowance on top of your studentship to help cover the costs of any additional support that a person studying for a doctorate might need as a result. We believe everyone deserves an excellent education and encourage students from all backgrounds and personal circumstances to apply.

Contact us

Have a question about this research opportunity or studying a PhD with us? Please get in touch with us, using the contact details below, and we’ll be happy to assist you.