Mid-Career Industry Fellowships - Grant ID: IM230100090
Funder
Australian Research Council
Funding Amount
$1,053,046.00
Summary
Multi material 3D Printing. This project aims to further develop a new 3D printing technique commercialised by an Australian start-up company. Current electronics manufacturing is extremely capital intensive, slow and restrictive in 3D design. The 3D printing method proposed in this application will disrupt the current advanced manufacturing eco system; creating unique methods to unlock advances in diverse markets for example, photovoltaics, printed circuit boards and sensors. The expected outco ....Multi material 3D Printing. This project aims to further develop a new 3D printing technique commercialised by an Australian start-up company. Current electronics manufacturing is extremely capital intensive, slow and restrictive in 3D design. The 3D printing method proposed in this application will disrupt the current advanced manufacturing eco system; creating unique methods to unlock advances in diverse markets for example, photovoltaics, printed circuit boards and sensors. The expected outcomes of this project are to create new commercial opportunities for the next generation of 3D printed electronics. This will provide significant benefits, creating unique capability to manufacture devices in 3D - faster, cheaper and with reduced reliance on global supply chains.Read moreRead less
Developing vitrimers: next generation reusable plastics. This project aims to develop a new class of advanced multifunctional polymer materials with the potential to underpin significant breakthrough capabilities for soft materials in general. The proposed work will relocate biological catalysts from their native, wet environment to solid organic engineering bio-sourced resins. Suitably selected enzymes will allow creation of polymer-based products that can be fully recyclable, with built-in pro ....Developing vitrimers: next generation reusable plastics. This project aims to develop a new class of advanced multifunctional polymer materials with the potential to underpin significant breakthrough capabilities for soft materials in general. The proposed work will relocate biological catalysts from their native, wet environment to solid organic engineering bio-sourced resins. Suitably selected enzymes will allow creation of polymer-based products that can be fully recyclable, with built-in properties such as self-healing, shape morphing, which are mechanically tunable, and have the ability to be reprocessed/recycled multiple times. This research will initiate a disruptive change in the application of biocatalysts for bio-based polymers.Read moreRead less