A Green and Fire-resistant Magnesium Oxychloride Cementitious Composite . This project aims to develop a novel and green fibre reinforced magnesium oxychloride cementitious composite with durability and resilience for buildings subject to fire/bushfire attack via well-integrated multiscale numerical and experimental studies. This enhances integrity and safety of buildings and increases the energy efficiency for buildings. The project will significantly advance the research and application of gre ....A Green and Fire-resistant Magnesium Oxychloride Cementitious Composite . This project aims to develop a novel and green fibre reinforced magnesium oxychloride cementitious composite with durability and resilience for buildings subject to fire/bushfire attack via well-integrated multiscale numerical and experimental studies. This enhances integrity and safety of buildings and increases the energy efficiency for buildings. The project will significantly advance the research and application of green cement, and find a solution for recycle and reuse a large amount of waste/industry by-products in construction towards circular economy. The research outcomes are innovative material, models, experiment technology and modelling methods, with significant impact and benefits to environment, economy and society. Read moreRead less
Hydrogen carbon waste into concrete: AI assisted nanoscience approach. The carbon waste from hydrogen production will be converted into carbon nanosheets on abundant construction materials for the creation of stronger and more durable concrete. Cutting-edge nanoscience-based experiments, as well as sophisticated modelling techniques including machine learning and finite element modelling, will be employed. The findings will drive advances in clean hydrogen production, carbon waste utilisation, c ....Hydrogen carbon waste into concrete: AI assisted nanoscience approach. The carbon waste from hydrogen production will be converted into carbon nanosheets on abundant construction materials for the creation of stronger and more durable concrete. Cutting-edge nanoscience-based experiments, as well as sophisticated modelling techniques including machine learning and finite element modelling, will be employed. The findings will drive advances in clean hydrogen production, carbon waste utilisation, cement hydration, nanotechnology and concrete technology for the next generation of an upskilled workforce and the promotion of a circular economy. This project will be carried out in collaboration with Australian and international renowned experts in computational modelling, nanomaterials and concrete materials.Read moreRead less
Three-dimensional printing of structures using fibre reinforced geopolymer concrete. This project aims to investigate geopolymer binders for cement. Three-dimensional printing using concrete can eliminate expensive formwork but is hampered by a lack of underpinning theoretical material and structural research. Conventional Portland cement’s setting characteristics limit its use for three-dimensional (3D) printing. The project will develop a theoretical framework for the structural properties of ....Three-dimensional printing of structures using fibre reinforced geopolymer concrete. This project aims to investigate geopolymer binders for cement. Three-dimensional printing using concrete can eliminate expensive formwork but is hampered by a lack of underpinning theoretical material and structural research. Conventional Portland cement’s setting characteristics limit its use for three-dimensional (3D) printing. The project will develop a theoretical framework for the structural properties of the 3D printed concrete and flow of geopolymer binder through aggregate bed, and design a fibre reinforcement system. This project is expected to improve construction, reduce injury rates and create high-end technology-based jobs.Read moreRead less