Selecteer de regio die het beste past bij je locatie of voorkeuren.
Deze instelling regelt de taal van de gebruikersinterface, inclusief knoppen, menu's en alle tekst op de site. Selecteer je voorkeurstaal voor de beste browse-ervaring.
Selecteer de talen voor vacatures die je wilt zien. Deze instelling bepaalt welke vacatures aan jou worden getoond.
The SOLVOMET group is the laboratory of metallurgical chemistry in the Department of Chemistry of KU Leuven and is led by Prof. Koen Binnemans. SOLVOMET’s vision is that metallurgical chemistry expertise allows to develop circular hydrometallurgical processes to provide the metals that are needed for the transition to a climate-neutral society. SOLVOMET’s dual mission is (1) to perform excellent research in metallurgical chemistry & solvent extraction, while training young researchers in these domains and (2) to support companies worldwide in the development of (solvent extraction-based) circular hydrometallurgical processes, and to provide training in solvent extraction. SOLVOMET’s is also applying its expertise in hydrometallurgy to the development of new electrolytes for redox flow batteries.
Website unit
The large-scale deployment of renewable technologies will require cost-effective battery technologies to support the electrical grid for industry and society. Solving this fundamental problem will enable the further expansion of renewable energy technologies, thus contributing to a CO2-neutral electricity supply. Such a technology needs to be scalable to a national grid level, demands a long service lifetime, and requires a low cost per kWh. Lithium-based battery technology has a good energy and power density, ideal for transport and small domestic applications. However, since it suffers from rapid performance degradation, production that is primarily reserved for automotive applications, high cost, and a strict safety management, they are not suitable for grid-scale storage applications. RFBs are an exciting alternative for large-scale applications: their performance is constant, without inherent degradation over time. With routine maintenance, even at the end of their theoretical lifetime (15 to 20.000 charge cycles), their performance will still be close to its original value. Moreover, the storage capacity of an RFB is not dependent on the electrode size but only on the volume of the electrolyte.6 State-of-the-art RFBs combine vanadium (V) electrolytes with fluorinated proton-conducting membranes. Although they have been studied for decades, their cost (esp. the electrolyte and membrane) is still a challenge for commercialization. In addition, vanadium is moderately toxic, and not really abundant and would need to be replaced to improve the safety of the system.
The objective of this PhD project is to develop new cerium and titanium-containing electrolytes that will be used to construct cerium-titanium RFBs with a Ce4+/Ce3+ catholyte in combination with a Ti4+/Ti3+ anolyte. Special attention will be paid to mixed-acid electrolytes that show higher solubilities, higher stability and faster redox kinetics compared to single-anion electrolytes. The targets are stable electrolytes with metal concentration above 2 mol L-1, resulting in a higher cell potential (1.7-1.75 V) than the all-vanadium system (1.2-1.3 V). The new electrolytes will be mixtures of methanesulphonic acid (MSA) and other inorganic acids. The research activities involve the determination of the solubility of the different salts as a function of the acid concentration and the temperatures, with special attention to the effect of mixed anions. The metal species present in the electrolyte solutions will be identified by a combination of different spectroscopic techniques, yielding complementary information, such as UV-VIS absorption spectroscopy, FTIR, Raman, 1D and 2D heteronuclear NMR spectroscopy (17O, 49Ti NMR for this project), electrospray ionisation mass spectrometry (ESI-MS), magnetic susceptibility measurements and X-ray absorption fine structure (XAFS, performed at ESRF in Grenoble (F) or at a beamline of another European synchrotron facility. The measured water activity is an indication of the deviation from ideal thermodynamic behavior. The information gathered will be used to build a thermodynamic model within the Mixed Solvent Electrolyte (MSE) framework. To determine the electrochemical properties of the electrolytes, different electrochemical techniques will be used, including cyclic voltammetry (CV) using stationary or rotating disk electrodes and spectroelectrochemistry. The diffusion coefficients and the radius of the diffusing electroactive species can be determined via chronoamperometric measurements and by application of the Cottrell and Stokes-Einstein equations. Experiments with a rotating disk electrode will allow the determination of limiting current, via the Levich equation.
We are looking for a highly motivated and talented candidate who meets the following requirements:
We offer:
For more information please contact Prof. dr. Koen Binnemans, mail: [email protected].
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.
De pagina van de werkgever bekijken