About the project
This project aims to rationally design efficient heterogeneous catalysts for sustainable application, including photocatalytic transformation for hydrogen production and CO₂ reduction. Objectives include analysing catalyst surface chemistry, building predictive microkinetic models, and synthesizing new catalyst architectures.
Photocatalytic transformations offer an elegant and powerful route for converting solar energy into chemical energy. These processes enable sustainable pathways such as hydrogen production via water splitting or reforming of organic compounds, as well as the reduction of CO₂ into value-added chemicals. However, conventional photocatalysts, e.g. titanium dioxide, often suffer from low efficiency, particularly due to their limited activity under visible light irradiation.
This project aims to design and develop novel heterogeneous photocatalysts capable of operating efficiently under visible light. To achieve this ambitious goal, we will employ an integrated computational–experimental strategy, combining advanced quantum chemical calculations with microkinetic modelling to guide the discovery and mechanistic understanding of a new class of photocatalytic materials. These theoretical insights will be complemented and validated by targeted experimental investigations.
The successful completion of this project will provide the scientific community with optimized catalytic systems for sustainable hydrogen production from organic feedstocks and offer promising technological solutions to current environmental and energy challenges. By advancing visible-light-driven photocatalysis, the project will contribute to addressing the global energy shortage while fostering broader societal awareness of sustainable hydrogen technologies. In the longer term, the proposed methodology will help illuminate alternative, environmentally responsible approaches to energy generation and resource utilization.
This is a multidisciplinary project involving reaction engineering and first-principle kinetic analyses. You'll benefit from a top-level research environment, as well as acquire skills at the interface between catalysis and microkinetic modelling. We will offer advanced trainings on heterogeneous reaction engineering, microkinetic modelling and DFT software (e.g. VASP, ONETEP, Gaussian09). You'll join a vibrant and well-established research group that is interested in the discovery and design of novel catalytic materials that address fundamental challenges in the chemical, environmental and energy landscape.
The School of Chemistry and Chemical Engineering is committed to promoting equality, diversity inclusivity as demonstrated by our Athena SWAN award. We welcome all applicants regardless of their gender, ethnicity, disability, sexual orientation or age, and will give full consideration to applicants seeking flexible working patterns and those who have taken a career break. The University has a generous maternity policy, onsite childcare facilities, and offers a range of benefits to help ensure employees’ well-being and work-life balance. The University of Southampton is committed to sustainability and has been awarded the Platinum EcoAward.
