Composite clad steel-geopolymer concrete systems for resilient structures. This project aims to develop innovative clad steel-geopolymer concrete composite members that will significantly improve the safe and economical design and construction of civil engineering systems. The expected outcomes will result in improved durability which has become a key issue in the economic justification of civil engineering infrastructure systems. Fire resistance in multi-storey buildings will also be improved t ....Composite clad steel-geopolymer concrete systems for resilient structures. This project aims to develop innovative clad steel-geopolymer concrete composite members that will significantly improve the safe and economical design and construction of civil engineering systems. The expected outcomes will result in improved durability which has become a key issue in the economic justification of civil engineering infrastructure systems. Fire resistance in multi-storey buildings will also be improved through this project, and the coupled use of clad steel and geopolymer concrete in composite systems will reduce consumption and contribute toward Net-zero structural design. This will provide considerable benefits to Australian structural engineers and constructors in advancing their capability in composite construction.Read moreRead less
Break the deadlock in corrosion research to prevent infrastructure collapse. Corrosion destroys one-quarter of the world’s annual steel production and costs the Australian economy $30 billion each year. This project targets a crucial missing link in understanding the structure and dynamics of the atomic lattices of corroded steel and the degradation of its mechanical strength. By combining advanced electrochemical and mechanical measurements with dynamics simulation of atomic lattices of corrode ....Break the deadlock in corrosion research to prevent infrastructure collapse. Corrosion destroys one-quarter of the world’s annual steel production and costs the Australian economy $30 billion each year. This project targets a crucial missing link in understanding the structure and dynamics of the atomic lattices of corroded steel and the degradation of its mechanical strength. By combining advanced electrochemical and mechanical measurements with dynamics simulation of atomic lattices of corroded steel, this project will produce the first concerted picture of corrosion induced strength degradation with a particular focus on real industrial conditions. This promises to guide the ongoing diagnosis of corrosion damages to steel, effectively preventing the collapse of corroded infrastructure.Read moreRead less