High throughput manufacture of hierarchical Li-Ion battery materials
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Despite continuous progress in both nanomaterial synthesis and assembly, there is a gap in industrially relevant technologies to scale-up the manufacturing of advanced nanomaterial structures. Combining advances in nanotechnology with emulsion templating and high throughput microfluidic techniques can offer a paradigm shift in how complex materials are processed and structured from the bottom-up. The ERC Consolidator Grant MIGHTY has demonstrated that microfluidic droplet generators can produce nanoparticle super-structures with controlled morphologies for applications in energy storage. More precisely, this process allows optimisation of Li-Ion battery electrode composition, porosity, and packing, which improves energy density and rate performance of Li-Ion batteries.
In this PoC Grant (HURRICANE) we seek additional support to scale up the particle manufacturing process to commercially relevant volumes, in order to translate the achieved performance benefits to commercial Li-ion battery electrode manufacture. This is particularly timely to support the EU's automotive industry as it transitions to electrical vehicles.
| University of Cambridge | LEAD_ORG |
Subjects by relevance
- Nanotechnology
- Accumulators
- Microfluidics
- Nanoparticles
- Nanomaterials
- Lithium-ion batteries
- Porosity
- Batteries
- Optimisation
- Emulsions
Extracted key phrases
- High throughput microfluidic technique
- High throughput manufacture
- Ion battery electrode manufacture
- Ion battery material
- Ion battery electrode composition
- Advanced nanomaterial structure
- Hierarchical Li
- Microfluidic droplet generator
- ERC Consolidator Grant MIGHTY
- Complex material
- Nanomaterial synthesis
- Emulsion templating
- Continuous progress
- Relevant technology
- Paradigm shift