PhD Studentship - Microbial Engineering of Novel Catalysts Hydrogen Production

Overview

Final date to receive applications: All year round

Research theme: Microbiology, Materials, Catalysis, Hydrogen

UK only

This 3.5-year PhD project is fully funded and home students, and EU students with settled status, are eligible to apply. The successful candidate will receive an annual tax-free stipend set at the UKRI rate (£20,780 for 2025/26) and tuition fees will be paid. We expect the stipend to increase each year. The start date is October 2026.

We recommend that you apply early as the advert may be removed before the deadline.

Hydrogen is increasingly seen as a critical component in achieving UK Net Zero targets. However, 80% of global hydrogen is produced via the Water-Gas Shift (WGS) reaction using iron–chromium catalysts, which are energy-intensive to produce and operate. Furthermore, chromium use raises significant health, environmental, and disposal concerns, prompting increasing regulatory and industrial pressure to find sustainable Cr-free alternatives. However, the design of Cr-free catalysts is hindered by a limited understanding of the impact of alternative dopants on the nanoscale structure and properties of these catalysts and how these features govern stability and activity in the WGS reaction.

Microorganisms offer a scalable platform for the synthesis of catalytic nanoparticles, including iron-based catalysts, under mild conditions. In addition, microbial incorporation of metal dopants can tune nanoparticle properties, significantly enhancing the catalytic activity. This project will exploit metal-reducing microorganisms to produce a suite of novel Cr-free biogenic catalysts, using controlled dopant incorporation and tailored microbial pathways to engineer catalyst structure and performance.

These materials will be analysed using advanced spectroscopic methods and electron microscopy to determine how dopants and biosynthesis conditions influence catalyst nanoscale structure. Finally, catalyst activity will be evaluated under WGS conditions to establish clear synthesis–structure–activity relationships to facilitate the rational design and development of sustainable, high-performance catalysts for hydrogen production.

The student will benefit from unique cross-disciplinary training, gaining experience in microbial cultivation, mineralogical analysis, and advanced characterisation techniques such as Scanning Transmission Electron Microscopy (STEM), Electron Energy Loss Spectroscopy (EELS). The student will also be supported through regular mentoring, professional development opportunities, and active integration into research groups across departments to help them develop strong networks with colleagues and collaborators.

Applicants are expected to hold, or about to obtain, a minimum upper second class undergraduate degree (or equivalent) in Environmental Science, Microbiology, Chemistry, Materials Science, Geosciences or a closely related discipline. A Masters degree in a relevant subject is desirable but not required.

To apply, please contact the main supervisor, Richard Kimber (Ric). Please include details of your current level of study, academic background and any relevant experience and include a paragraph about your motivation to study this PhD project.

Final date to receive applications: All year round

Stipend
: £20,780 - please see advert