Projects

ThermIon

The ThermIon project is innovating lithium extraction by means of the ion-pumping technique. Committed to improving electrode material properties and performance, the team is performing electrochemical analysis and modelling. The project’s ambition lies in optimizing efficiency, performance, and long-term stability of the lithium extraction process through advanced theoretical models and rigorous experimental analysis, thereby revolutionizing the future of sustainable energy.

Humans on Mars

Producing oxygen and hydrogen in situ is crucial for space travel and life support systems. Electrolysis breaks down water into oxygen and hydrogen, but the "bubble effect", which is influenced by gravity, significantly impacts performance. This project focuses on exploring the bubble effect on flat or nanostructured electrodes to enhance electrolyzer design and efficiency in low-gravity environments. By combining cutting-edge materials science, advanced electro-analytical techniques, and multi-phase, mutli-scale fluid dynamics, we aim to push the boundaries of space technology.

NeuroBatt

Predicting precisely the state of health of lithium-ion batteries for posterior cycles is an important step towards improvement of lifetime and thus sustainability. The project NeuroBatt aims to use a complete picture of data such as voltage, current, impedance and temperature of each cell in a battery back to dfine a prediction model based on machine learning techniques in order to detect aging in an early state.

ElIonT

In this project, we will perform a fundmental investigation of electrochemical processes, aimed at a long-term improvement of the technological level of electrochemical devices. During the project, we will develop a phenomenological theory of electron and ion transfer processes that extends the current theories (in particular, Marcus-Hush theory). The theory will take into account non-ideal effects in concentrated solutions and double layer charge effects (Frumkin effect). The experimental methods will include dynamic impedance spectroscopy hyphenated with quartz crystal microbalance.

ZIB

Aqueous zinc-ion batteries (ZIBs) are attracting great attention as alternative low cots and environmentally friendly energy storage systems. Therefore, we are focusing on the development of aqueous ZIBs with higher power density and long cycle life, with an approach crossing the borders of fundamental electrochemistry, material science, multi frequency analysis, and modeling.