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The two PhD positions are part of the Global PhD Partnership program between KU Leuven (Belgium) and Melbourne University (Australia). One Joint PhD project will be primarily based at the KU Leuven with secondment at the University of Melbourne. Vice versus, the other Joint PhD will be mainly based at Melbourne University with the secondment in Leuven. The supervisory team involves Prof. Xing Yang (KU Leuven, Department of Chemical Engineering), Prof. Ivo Vankelecom (KU Leuven, Department of Bio-Science Engineering), Dr. Chen George and Dr. Mengran (Aaron) Li from Melbourne University (Department of Chemical and Biomedical Engineering).
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Project description:
Despite being an attractive concept, the performance of CO2 reduction and conversion reactions via electrochemical process (e.g. electrolysis) is still facing critical challenges that prevent its practical implementation. In particular, the lack of proficient membranes in terms of alkaline stability and low ion selectivity (to hydroxyl ion) has hindered the commercial adaptation of membrane electrode assemblies (MEAs) for CO2 electrolysis. The KUL project will develop a new class of anion exchange membranes tailored for MEA applications, helping to improve the process performance and energy efficiency. Firstly, anion exchange membranes will be designed with high ion exchange capacity and high tolerance to a wide range of pH and solvent conditions that simulates the harsh environment in MEA; Secondly, the AEM will be further tailored to impart high hydroxyl conductivity and selectivity against co-existing anions. With these membranes, we aim to overcome several classical trade-off relationships in AEM used in CO2 electrolysers, such as the selectivity vs. ion transport rate. Lastly, the as-developed membranes will be evaluated in the full MEA system at the University of Melbourne, to understand the correlation of the membrane characteristics and MEA performance in terms of chemical conversion and energy efficiency. The successful outcomes of this project will pave the way for the development of future generation membrane-based CO2 electrolyser, which not only serves as a promising alternative means for carbon reduction, but also a sustainable technology to convert CO2 to useful products.
Joint PhD project 1 will be primarily based at the KU Leuven with a minimum 12-month stay at the University of Melbourne.
Project description:
Electrochemical reduction of carbon dioxide (CO2) presents a promising pathway to mitigate climate change by transforming CO2 into valuable chemicals and fuels. Anion Exchange Membranes (AEMs), a key component in electrochemical reactors such as Membrane Electrode Assembly (MEA), play a crucial role in providing high transport rate of hydroxide ions and in rejecting other ionic species. For CO2 electrolysis to be economically viable in industrial scale, MEAs need to offer superior conversion efficiency and selectivity, as well as sufficient long-term stability. Based at Melbourne, this project will experimentally investigate anion transport across AEMs in alkaline conditions, as well as the performance of AEMs in CO2 electrolysis after long-term exposure to the complex alkaline environment. There is also an opportunity to explore computational modeling of this electrochemical process at KU Leuven to gain new insights on the influence of the micro-environments on ion transport behavior. This multidisciplinary project will develop new understanding in the stability of ion exchange membranes and their ion transport mechanisms in CO2 electrolysis processes, paving the way for rational design of robust ion exchange membranes to enhance their efficiency, selectivity and longevity in CO2 conversion applications.
Joint PhD project 2 will be primarily based at the University of Melbourne with a minimum 12-month stay at KU Leuven.
Supervision team:
KU Leuven:
Principal Supervisor: Prof Xing Yang
Co-supervisor: Prof Ivo Vankelecom
The University of Melbourne:
Principal Supervisor: Dr George Chen
Co-supervisor: Dr Mengran (Aaron) Li
If you are highly motivated researchers in the areas of Chemical Engineering with passion in separation technology for sustainability, you are strongly encouraged to enquire and apply.
Profile required:
Application Documents:
Interested candidates please send through your academic transcripts during Bachelor and Master studies. A comprehensive resume including your full list of publications and project experiences, a research statement outlining your main research interest, evidence of language proficiency if applicable, and names of three referees.
One successful candidate will be offered a PhD fellowship at KU Leuven and Melbourne University, respectively, to become part of our international teams with global research links to work towards a PhD. Funding can be provided for a period of 4 years. The tuition fee for scholarship holders will be waived. The commencement date is as soon as possible.
https://research.kuleuven.be/portal/en/project/3E240350
For more information please contact Prof. dr. Xing Yang, tel.: +32 16 37 46 72, mail: xing.yang@kuleuven.be.
KU Leuven strives for an inclusive, respectful and socially safe environment. We embrace diversity among individuals and groups as an asset. Open dialogue and differences in perspective are essential for an ambitious research and educational environment. In our commitment to equal opportunity, we recognize the consequences of historical inequalities. We do not accept any form of discrimination based on, but not limited to, gender identity and expression, sexual orientation, age, ethnic or national background, skin colour, religious and philosophical diversity, neurodivergence, employment disability, health, or socioeconomic status. For questions about accessibility or support offered, we are happy to assist you at this email address.
KU Leuven is an autonomous university. It was founded in 1425. It was born of and has grown within the Catholic tradition.
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