What do all these products have in common? The materials they are made of typically contain special nanostructures called ‘hetero-aggregates’, consisting of two or more types of nanoparticles mixed together. Nowadays, these unique materials are crucial components in batteries, solar panels, medicines, and many other products that we rely on. Hetero-aggregates are created when two or more different types of nanoparticles interact with each other on a microscopic scale, creating new, synergistic properties that wouldn’t be possible with just one type alone. However, producing these useful interactions isn’t easy. Read More
One way to produce a hetero-aggregate is to take two or more powders, each containing just one type of nanoparticle, and mixing them together. With this approach, however, particles of the same type will often clump together, limiting their functionality.
To unlock their full potential, the nanoparticles need to be manufactured and mixed in a controlled way to ensure they are evenly dispersed – a term specialists use to describe how particles are spread out. This maximizes the number of beneficial contacts between different types of particles.
This is the focus of the Priority Programme 2289: Hetero-Aggregates – an ambitious research effort currently taking place in Germany, spearheaded by researchers at the University of Bremen. The initiative brings together 19 research groups from across Germany, each tackling a different piece of a complex puzzle.
Currently, the researchers are exploring several key areas to unlock the full potential of hetero-aggregates:
First, some teams are delving into innovative synthesis processes. Techniques such as spray-flame pyrolysis and electro-spray processes are among the cutting-edge methods being studied, to ensure the highest possible number of contacts between different nanoparticle types.
A second key area is measurement technology. To understand the formation of such complex nanostructures, researchers are focusing on improving measurement accuracy, while others use powerful imaging methods to visualise the intricate structures of hetero-aggregates.
A third area focuses on developing sophisticated simulations of hetero-aggregation processes. Even with the most advanced measurement technology, not all aspects of these deeply complex structures can be observed. Computer simulations help to fill in the gaps, guiding experiments and enabling better predictions about the larger-scale properties of hetero-aggregates.
Given the complexity of this research, collaboration is key. To ensure the best possible results, researchers across all different groups of the Priority Programme 2289 are working together, sharing data, equipment, and expertise. Sometimes this means visiting each other’s labs to work side-by-side, ensuring that every piece of the puzzle fits together seamlessly.
This collaborative effort is what makes the Priority Programme 2289 so special. Launched in 2021 and supported by the German Research Foundation, this six-year initiative is all about creating synergies in tailor-made mixtures of nanoparticles. The ultimate goal is to unlock the mysteries of hetero-aggregates, towards uncovering new capabilities in the technologies that power our everyday lives.