Controlling alkali-silica reaction in concrete for road pavements and bridge using graphene oxide and dune sand. This project aims to formulate a new mix design for sustainable and resilient infrastructure materials with radically improved material properties and performance, as well as reduced life cycle cost and impact on the environment and societies. The aim of the project is to investigate the effect of dune sand and graphene oxide on mechanical properties and durability of concrete composi ....Controlling alkali-silica reaction in concrete for road pavements and bridge using graphene oxide and dune sand. This project aims to formulate a new mix design for sustainable and resilient infrastructure materials with radically improved material properties and performance, as well as reduced life cycle cost and impact on the environment and societies. The aim of the project is to investigate the effect of dune sand and graphene oxide on mechanical properties and durability of concrete composites including properties and strength relation and alkali-silica reaction in concrete. The optimal mix design will be supported by the understanding of the interaction between graphene oxide, water molecules, dune sand and cement at nanolevel via scanning electron microscopy (SEM) and molecular dynamics simulations.Read moreRead less
Novel Hydrophobic Concrete for Durable and Resilient Mining Infrastructure. The mining field is harsh with various corrosive media that cause rapid deterioration and ageing of concrete. This project aims to develop a novel hydrophobic concrete with integrated water-proofing and self-healing capacities and optimise its efficacy and cost-effectiveness for durable and resilient mining infrastructure using hybrid water-repellent nanoparticles and raw crystalline admixtures. The new hydrophobic concr ....Novel Hydrophobic Concrete for Durable and Resilient Mining Infrastructure. The mining field is harsh with various corrosive media that cause rapid deterioration and ageing of concrete. This project aims to develop a novel hydrophobic concrete with integrated water-proofing and self-healing capacities and optimise its efficacy and cost-effectiveness for durable and resilient mining infrastructure using hybrid water-repellent nanoparticles and raw crystalline admixtures. The new hydrophobic concrete is expected to significantly improve structural safety, durability, and service life of mining infrastructure while simultaneously reducing protection costs, repair needs, and reconstruction. The outcomes will offer desirable benefits for Australia’s mining industry, with significant reductions in maintenance costs.Read moreRead less
Flame-Retarding and Mechanically Resilient Elastomer Composites. This project will develop a new generation of flame-retarding and mechanically resilient elastomer composites by taking advantage of nanoscale effect and synergy. The outcomes will be two types of flame-retarding additive pellets and their elastomer composites; these pellets also suit other polymers such as thermoplastics. The elastomer composites are expected to have excellent flame retardancy, mechanical properties, and fatigue p ....Flame-Retarding and Mechanically Resilient Elastomer Composites. This project will develop a new generation of flame-retarding and mechanically resilient elastomer composites by taking advantage of nanoscale effect and synergy. The outcomes will be two types of flame-retarding additive pellets and their elastomer composites; these pellets also suit other polymers such as thermoplastics. The elastomer composites are expected to have excellent flame retardancy, mechanical properties, and fatigue performance, to meet the demands from industrial partners. The project will provide a platform for elastomer manufacturing industry to develop flame-retarding, high-performance products for domestic applications and for export. Read moreRead less
Thermoelectric devices for high-performing localised coolers. This project aims to develop a lightweight, low-energy-consumption, and high-durability wearable thermoelectric cooler for localised cooling using a novel industry-led approach, coupled with device design and materials engineering strategies. The key breakthrough expected is to design wearable thermoelectric coolers by using flexible substrates and thermoelectric materials with engineered chemistry and unique structures for achieving ....Thermoelectric devices for high-performing localised coolers. This project aims to develop a lightweight, low-energy-consumption, and high-durability wearable thermoelectric cooler for localised cooling using a novel industry-led approach, coupled with device design and materials engineering strategies. The key breakthrough expected is to design wearable thermoelectric coolers by using flexible substrates and thermoelectric materials with engineered chemistry and unique structures for achieving localised, instant, and controllable cooling with super low power input for personal usage in building and mining industry. Expected outcomes include innovative technologies for achieving high-efficiency cooling, which will provide significant economic and commercial benefits for Australia.Read moreRead less
Field scale biocementation in remediation and self-healing . This project aims to address the challenges of field applications and commercialisation of biocementation technology. Biocementation is the process through which Nature, with the help of microbes builds large and durable carbonate formations such as corals and beach rocks. This is emerging as a clean technology that alleviates the sustainability challenges faced by the construction industry. Microorganisms especially suited to Australi ....Field scale biocementation in remediation and self-healing . This project aims to address the challenges of field applications and commercialisation of biocementation technology. Biocementation is the process through which Nature, with the help of microbes builds large and durable carbonate formations such as corals and beach rocks. This is emerging as a clean technology that alleviates the sustainability challenges faced by the construction industry. Microorganisms especially suited to Australian conditions will be developed focusing on optimum use of resources for economic and environmental viability. Biocementation products will be developed for easy field application and self-healing concrete and bioremediation will be attempted on deteriorated structural systems. This technology has the potential to usher in the era of biologisation of construction.Read moreRead less
Engineering Nanoionic Interfaces towards High Performance Cathode Coatings. This project aims to develop novel cathode coating materials towards more durable and powerful energy storage devices. Lithium ion battery will be constructed based on perovskite oxides to provide high capacity and stability for potential applications in electric cars, mobile phones and internet of things. The project will address fundamental challenges in this field by developing high voltage cathode coated with nanoion ....Engineering Nanoionic Interfaces towards High Performance Cathode Coatings. This project aims to develop novel cathode coating materials towards more durable and powerful energy storage devices. Lithium ion battery will be constructed based on perovskite oxides to provide high capacity and stability for potential applications in electric cars, mobile phones and internet of things. The project will address fundamental challenges in this field by developing high voltage cathode coated with nanoionic thin layers. Combined with new materials fabrication techniques and innovative strain engineering, the expected outcome is high performance cathodes with enhanced rate capability and cycling life, low fabrication cost and production scalability.
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Advanced shield materials for compact fusion energy. We aim to predict how materials used for shielding sensitive components in nuclear fusion reactors will degrade over time. We will use this knowledge to design advanced alloys for radiation shield, which are critical for the development of more compact fusion reactors design, with lower construction cost, and shorter assembly time. These advanced shield materials may also be used in other applications in radiation fields (e.g. space, nuclear m ....Advanced shield materials for compact fusion energy. We aim to predict how materials used for shielding sensitive components in nuclear fusion reactors will degrade over time. We will use this knowledge to design advanced alloys for radiation shield, which are critical for the development of more compact fusion reactors design, with lower construction cost, and shorter assembly time. These advanced shield materials may also be used in other applications in radiation fields (e.g. space, nuclear medicine). The project also seeks to extend the Australian nuclear research capability by developing an innovative technique to study radiation damage using the OPAL reactor at ANSTO.Read moreRead less
Lightweight Photovoltaic Modules for Low-Load Capacity Building Roofs. This project aims to develop lightweight and reliable high efficiency photovoltaic modules that expand solar energy installations onto low-load capacity building roofs. New lightweight materials will be developed for packaging with multi-functionalities such as fast heat dissipation. This project will produce economical prototypes and enable and
facilitate cost reduction of crystalline silicon photovoltaic module installation ....Lightweight Photovoltaic Modules for Low-Load Capacity Building Roofs. This project aims to develop lightweight and reliable high efficiency photovoltaic modules that expand solar energy installations onto low-load capacity building roofs. New lightweight materials will be developed for packaging with multi-functionalities such as fast heat dissipation. This project will produce economical prototypes and enable and
facilitate cost reduction of crystalline silicon photovoltaic module installations on lightweight buildings, overcoming current constraints of heavy glass modules and making more solar energy exploited in both Australia’s urban and rural areas. This will get steps closer to zero emission buildings, by providing renewable energy alternative to conventional fossil fuel-based power generation.Read moreRead less
Elastomer/Graphene Composites for Reinforcement at Low Strain. This project aims to develop new elastomer/graphene composites by designing and fabricating graphene precursors which can transform into graphene sheets during melt compounding with elastomers. These sheets have tunable surface affinity with elastomers, to attain expected dispersion in elastomers for effective reinforcement at low strain. The dominant filler in industry – carbon black – is ineffective at low strain. The outcomes are ....Elastomer/Graphene Composites for Reinforcement at Low Strain. This project aims to develop new elastomer/graphene composites by designing and fabricating graphene precursors which can transform into graphene sheets during melt compounding with elastomers. These sheets have tunable surface affinity with elastomers, to attain expected dispersion in elastomers for effective reinforcement at low strain. The dominant filler in industry – carbon black – is ineffective at low strain. The outcomes are anticipated to transform the current manufacturing practice of rubber products for applications in agricultural, automobile, construction, medical and mining industries.Read moreRead less
Concrete Mixes for Durability: A Hybrid Mathematical Optimisation Approach. This project will lead a paradigm shift in concrete mix design methodology, which is currently focused on meeting the mechanical performance objectives of concrete, to a holistic approach that maximises durability of concrete alongside its mechanical performance. The approach is based on a hybrid methodology involving mathematical optimisation of concrete mix based on empirically formulated objective functions for durabi ....Concrete Mixes for Durability: A Hybrid Mathematical Optimisation Approach. This project will lead a paradigm shift in concrete mix design methodology, which is currently focused on meeting the mechanical performance objectives of concrete, to a holistic approach that maximises durability of concrete alongside its mechanical performance. The approach is based on a hybrid methodology involving mathematical optimisation of concrete mix based on empirically formulated objective functions for durability properties and mechanical properties. The multi-objective nature of proposed optimisation model will allow simultaneous consideration of several design objectives including: minimising the overall risk of cracking, minimising the permeability; and maximising the rate of strength development. Read moreRead less