Discovery Early Career Researcher Award - Grant ID: DE120102906
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Topology optimisation for advanced engineered nanostructures. Advanced technological innovation requires extraordinary material properties, which can be generated directly from engineered nanostructures by manipulating surface plasmon resonances. The project will develop a new computational method for nanostructural design and expect to benefit aerospace, biomedical, optical and energy engineering fields.
Onset Theory: Pushing the design envelope for textile composite structures. This study aims to exploit an innovative physics-based approach to predict the strength of textile composites. This is particularly important in areas such as aircraft design, where drastic weight savings are needed to allow designers to remain competitive in a low-carbon future. Improved theory and design tools will remove conservatism and account for a large part of these weight savings. The new approach is the first t ....Onset Theory: Pushing the design envelope for textile composite structures. This study aims to exploit an innovative physics-based approach to predict the strength of textile composites. This is particularly important in areas such as aircraft design, where drastic weight savings are needed to allow designers to remain competitive in a low-carbon future. Improved theory and design tools will remove conservatism and account for a large part of these weight savings. The new approach is the first to be consistent at all length scales — from atoms to aeroplanes — ensuring relevance for new and evolving composite material systems. A novel understanding of crack initiation in textile laminates is intended to reduce design and certification effort for new aircraft and help to design more efficient airframes at a lower cost.Read moreRead less