Six tenure track researchers will focus on ECCM Research
ECCM MVI Top-Up Call matchmaking has been rescheduled
Six PhD graduates from the Netherlands and abroad will soon start work in a tenure track position in the field of Electrochemical Conversion and Materials (ECCM) at a Dutch host institution. These positions have been filled as part of the Electrochemical Conversion and Materials Tenure Track Call. The six tenure track researchers will also take part in the ECCM MVI Top-Up Call, designed to bring about collaboration with researchers in the humanities and social sciences for the purpose of addressing the societal aspects of innovations resulting from research into Electrochemical Conversion and Materials. Publication of the ECCM MVI top-up call was expected in March. The matchmaking event had been scheduled for 28 April 2020. Both will be moved to a later date in line with measures introduced to slow the spread of the coronavirus.
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About the ECCM Tenure Track and ECCM MVI Top-Up Call
In 2020, the Dutch Research Council (NWO) will fund six tenure track positions for research into Electrochemical Conversion and Materials as part of the ECCM Tenure Track Call. ECCM allows energy from electricity to be stored in chemical compounds, such as hydrogen. In doing so, ECCM provides a key to the new innovations demanded by society and can therefore open the door to great economic opportunities. In this ECCM Tenure Track Call, socially responsible innovation will be integrated through an ECCM MVI Top-Up Call.
ECCM MVI Top-Up Call: matchmaking and deadlines rescheduled
The ECCM MVI Top-Up Call appeals to researchers in the humanities and social sciences to collaborate with the researchers from the ECCM Tenure Track Call to address the societal aspects of innovations resulting from research into Electrochemical Conversion and Materials (ECCM). NWO had planned to organize a matchmaking event on 28th of April 2020 to provide more information about the call and to connect the researchers from the humanities and social sciences with the ECCM tenure track researchers by means of speed dates. However, this matchmaking event will be postponed until a later date in line with the NWO corona virus measures. The ECCM MVI Top-Up Call won’t be published in March as mentioned earlier. Keep an eye on the NWO website and newsletter for all relevant information concerning the call and the matchmaking.
Below you can find a summary of each of the six tenure tracks due to get underway, presented in alphabetical order:
Tenure track #1 | Dr M.A. Altomare, University of Twente
Nanostructured electrodes harness renewable electricity in electrochemical production of chemicals and sustainable waste-water treatment
Nanosized metal particles will be formed by exposing a thin metal film to high temperatures, a process known as ‘dewetting’. Under optimum conditions, this method produces particles with a specific crystal orientation and composition, making it possible to bring about crystal plane-dependent electrochemical reactions with high precision. Several reactions will be investigated, including hydrogenation of pyrolysis oil components, reductive conversion of nitrate in surface water and synthesis of hydrogen peroxide. An electrochemical approach to purification processes of this kind can play a significant part in making the chemical industry more sustainable and reducing greenhouse gas emissions.
Tenure track #2 | Dr A.C. Garcia, University of Amsterdam
An electrifying combination
Combining renewable electricity with organic chemistry to make the chemical industry more sustainable is an approach that holds great promise. This project studies both fundamental and applied aspects of adding value to organic molecules through reaction with simple carbon and nitrogenous building blocks, such as carbon dioxide and ammonia.
Tenure track #3 | Dr P.B. Groszewicz, Delft University of Technology
Electroceramic materials for a CO2-free future
Renewable energy sources such as solar and wind power tend to be unpredictable in terms of the energy they can generate at any given time. Nevertheless, they provide the key to a CO2-neutral and fossil-free society. Finding efficient ways to store electricity and convert it into synthetic fuels is an essential step towards a successful energy transition. Electroceramics are integral to solid oxide cells for chemical conversion in battery materials and power electronics. This project will deploy spectroscopy and neutron scattering techniques to develop new electroceramic materials to make the above applications possible and contribute to the energy transition.
Tenure track #4 | Dr L.W. Kiewidt, Wageningen University & Research
Green electricity for green molecules: electrocatalytic upgrading of biomass
Biomass offers a renewable alternative to fossil sources for the production of materials and chemicals. To fully realize this potential, biomass molecules need to be chemically modified. Using green electricity to directly convert these molecules through electrochemical reactions enables the genuinely sustainable production of materials and chemicals from renewable sources. To make sure that conversion results in the desired product, unique materials called electrocatalysts are required. This project aims to develop customized electrocatalysts capable of efficiently converting biomass in order to power the transition to a sustainable circular economy.
Tenure track #5 | Dr R.V. Mom, Leiden University
Zooming in on the hydrogen economy: insights at atomic level with advanced spectroscopy
The concept behind the hydrogen economy is splitting water into hydrogen and oxygen using surplus electrical power from wind and solar sources. This process can then be reversed when solar and wind power are in short supply. An inspired idea but also a costly one, due to the inefficiency and degradation of the electrodes that produce or convert oxygen. This project will go to the heart of these problems. By developing advanced X-ray spectroscopic techniques, I will enable the observation of electrodes at atomic level. This will allow me to pinpoint the parts of the atomic structure that determine electrode efficiency and degradation.
Tenure track #6 | Dr M. Pérez-Fortes, Delft University of Technology
Addressing the multi-scale challenge of implementing electrochemical conversion
The electrochemical conversion of CO2 can support the transition to a sustainable energy system. This approach can store energy while opening up a new route for the production of chemicals. The successful application of electrochemical CO2 conversion will depend on our ability to find the most effective combinations of technologies, business models and socio-economic strategies. The aim of this project is to develop a novel assessment framework for CO2 electrochemical systems at different scales by integrating insights from technology, economics, value chains and policy.