Project description
Innovation reveals the correlated activity and properties of single nanoparticles
Studying particles whose size is on the scale of about a few hundred atoms (nanoparticles or NPs) is no easy task. However, characterising the intrinsic activity of specific NPs and correlating that to their properties is critical to designing NPs for applications. Among these is the use of transition metal-based NPs for electrocatalysis, instead of conventional scarce metal-based catalysts. The EU-funded MITICAT project is developing a technique to observe the activity of single NPs acting as catalysts of a sluggish yet critical reaction for renewable energy conversion. The ability to measure the intrinsic activity and physical properties of individual NPs in situ could lead to a step change in electrocatalysis and energise the transition to renewables.
Objective
Transition metal based nanoparticles (NPs) are envisioned as viable alternatives to the scarce precious metal based catalysts used today for renewable energy conversion. Yet, probing their intrinsic activity to establish property-activity relations and so to smartly design superior catalysts, is impeded by two limitations of existing electrocatalytic techniques. First, the integral assessment of ensembles of non-identical NPs prohibits the identification of intrinsic activity differences. Second, the unknown effects of additives required analyzing the activity of often poorly conductive transition metal oxides, e.g. during the oxygen evolution reaction (OER), prohibit the access to quantitative data and comparable benchmarks. Very recently, we have proposed single NP electrochemistry to overcome both limitations. We demonstrated that the electrocatalytic OER response of individual CoFe2O4 NPs can be assessed in the absence of additives. However, we have not been able to extract property-activity relations, as NP characterization was limited to ex situ data. The groundbreaking strategy of this work is to combine intrinsic activity and physical property measurements of individual NPs. Physical characterization will comprise different online and ex situ methods to gain comprehensive property information. Numerical simulations will allow us to extract quantitative kinetic data from the electrochemical studies, allowing us to provide quantitative benchmarks of intrinsic catalyst performance. Cycling of NPs in a microfluidic platform will enable degradation studies and systematic modification “on the fly”. Moving towards application conditions, catalyst-support interactions will be studied by stepwise immobilization of catalysts on substrates. As a result of revealing intrinsic property-activity relations in electrocatalysis and of elucidating catalyst-support interactions, we will gain the understanding urgently needed to disruptively change electrocatalyst devolopment.
Fields of science
Not validated
Not validated
- natural scienceschemical scienceselectrochemistry
- natural scienceschemical sciencesinorganic chemistryinorganic compounds
- natural scienceschemical sciencescatalysiselectrocatalysis
- engineering and technologynanotechnologynano-materials
- engineering and technologyenvironmental engineeringenergy and fuelsenergy conversion
Programme(s)
Topic(s)
Funding Scheme
ERC-STG - Starting GrantHost institution
44801 Bochum
Germany