Hybrid Toughening of Carbon Fibre Composites for Liquid Hydrogen Storage. This project aims to develop hybrid toughening technologies to overcome the major problem of transverse matrix cracking and splitting in existing carbon fibre composites when subjected to thermal-mechanical loading at the ultracold liquid hydrogen temperature. Nano-toughened thin-ply carbon fibre layers will be hybridised with standard-ply laminates to sustain internal pressure and external impact loading at cryogenic temp ....Hybrid Toughening of Carbon Fibre Composites for Liquid Hydrogen Storage. This project aims to develop hybrid toughening technologies to overcome the major problem of transverse matrix cracking and splitting in existing carbon fibre composites when subjected to thermal-mechanical loading at the ultracold liquid hydrogen temperature. Nano-toughened thin-ply carbon fibre layers will be hybridised with standard-ply laminates to sustain internal pressure and external impact loading at cryogenic temperatures without leaks. The hybrid composites are expected to enable Australian companies to engineer, manufacture and export lightweight carbon fibre tanks for storing and exporting liquid hydrogen, which is emerging as a transformational opportunity for Australia to become a global supplier of green energy.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100032
Funder
Australian Research Council
Funding Amount
$456,547.00
Summary
Chemical and structural design for high power energy storage materials. This project aims to develop new materials with both high power and high energy storage capabilities by exploring emerging relaxor antiferroelectric (RAFE) materials. Through investigating the internal chemical and structural factors, and their interactions at different length scales, this project will first solve the current ambiguities in RAFEs and then identify critical factors for properties to better design and develop ....Chemical and structural design for high power energy storage materials. This project aims to develop new materials with both high power and high energy storage capabilities by exploring emerging relaxor antiferroelectric (RAFE) materials. Through investigating the internal chemical and structural factors, and their interactions at different length scales, this project will first solve the current ambiguities in RAFEs and then identify critical factors for properties to better design and develop new high-performance energy storage materials. The outcomes of this project will advance the knowledge of ferroic materials, provide new candidates for advanced electrical systems such as renewable energy, electric vehicles and pulsed power devices, and potentially revolutionise high power energy storage technologies.Read moreRead less