Laser cleaning processes for Roads and Maritime Services bridges. This project aims to develop innovative laser cleaning processes to conserve the structural integrity and iconic status of the Sydney Harbour Bridge. New laser technologies offer the opportunity to remove lead-based paint and clean the bridge’s metal structures and granite pylons offering advantages unavailable with current techniques. The expected outcomes will be new best-practice laser conservation techniques usable for both ha ....Laser cleaning processes for Roads and Maritime Services bridges. This project aims to develop innovative laser cleaning processes to conserve the structural integrity and iconic status of the Sydney Harbour Bridge. New laser technologies offer the opportunity to remove lead-based paint and clean the bridge’s metal structures and granite pylons offering advantages unavailable with current techniques. The expected outcomes will be new best-practice laser conservation techniques usable for both hand-held and automated systems to preserve one of the most iconic bridges in the world. This will reduce maintenance frequency and cost, restore the beauty of the bridge, retain its engineering significance and provide a baseline process for cleaning of other historical large scale metal and stone heritage objects.Read moreRead less
A national framework for managing malignant plastics in museum collections. A national framework for managing malignant plastics in museum collections. This collaborative project between three universities, four museums and an art gallery aims to discover how to predict and increase the lifespan of malignant plastics or polymers by studying their identification, deterioration and conservation. 5 to 80% of museum collections, composed of growing numbers of plastic or polymer-based materials, need ....A national framework for managing malignant plastics in museum collections. A national framework for managing malignant plastics in museum collections. This collaborative project between three universities, four museums and an art gallery aims to discover how to predict and increase the lifespan of malignant plastics or polymers by studying their identification, deterioration and conservation. 5 to 80% of museum collections, composed of growing numbers of plastic or polymer-based materials, need better preservation. Conservators do not have much expertise in preserving plastics, which are contemporary and have a relatively short life expectancy. This project intends to provide museums with a model for prioritising and effectively allocating resources to preserve a vulnerable group of collections for future generations.Read moreRead less
Core loss mechanisms in soft magnetic nanostructures. This project aims to clarify the mechanism of power losses in magnetic cores used in the petrol-electric hybrid cars by investigating the relationship between the core losses and magnetic correlation lengths in iron alloys. This project expects to generate new knowledge on the effect of magneto-mechanical interaction on the anomalous core loss in iron based alloys. The intended outcomes include an experimental confirmation of the random aniso ....Core loss mechanisms in soft magnetic nanostructures. This project aims to clarify the mechanism of power losses in magnetic cores used in the petrol-electric hybrid cars by investigating the relationship between the core losses and magnetic correlation lengths in iron alloys. This project expects to generate new knowledge on the effect of magneto-mechanical interaction on the anomalous core loss in iron based alloys. The intended outcomes include an experimental confirmation of the random anisotropy model, a major theoretical model in nanostructured materials and identification of ideal magnetic domain configurations for lower power losses. These intended outcomes should bring great benefits to the development of low-carbon vehicle technologies for sustainable motorisation in Australia.Read moreRead less
Development of Novel Concrete Noise Walls Incorporating Recycled Materials. This project will develop high-performance, lightweight, concrete noise walls and acoustic barriers that use recycled tyre and glass products to improve sound absorption, and address environmental problems associated with the mining of river sands, and stockpiling of waste tyre and glass products. Innovation in noise wall technology consists in developing low-carbon concrete mixes (using less cement) with a maximum amoun ....Development of Novel Concrete Noise Walls Incorporating Recycled Materials. This project will develop high-performance, lightweight, concrete noise walls and acoustic barriers that use recycled tyre and glass products to improve sound absorption, and address environmental problems associated with the mining of river sands, and stockpiling of waste tyre and glass products. Innovation in noise wall technology consists in developing low-carbon concrete mixes (using less cement) with a maximum amount of recycled product, together with reducing wall thickness, while maintaining the necessary engineering properties such as acoustics, strength, and durability. In addition to higher acoustic insulation, the novel low-carbon, lightweight, panels will improve material handling and affordability of noise barriers.Read moreRead less
Advanced Fibre Interfaces in Active Water Management Systems. Flooding is a critical issue in Australia, generating considerable economic losses, including by stormwater contamination. The current project will pioneer an integrated solution for stormwater retention, while removing chemical pollutants. In collaboration with the company ROCKWOOL-Lapinus - based on a stonewool fibre platform - we will (i) design fibre coatings based on a versatile and chemically simple deposition process, (ii) inco ....Advanced Fibre Interfaces in Active Water Management Systems. Flooding is a critical issue in Australia, generating considerable economic losses, including by stormwater contamination. The current project will pioneer an integrated solution for stormwater retention, while removing chemical pollutants. In collaboration with the company ROCKWOOL-Lapinus - based on a stonewool fibre platform - we will (i) design fibre coatings based on a versatile and chemically simple deposition process, (ii) incorporate functionalities onto the fibres allowing active stormwater treatment to e.g. retain pollutants or target heavy metals and (iii) investigate these interfaces in-depth by advanced surface and interface characterisation methods to understand the fibre interface properties from nano- to macroscale.Read moreRead less
Next generation easy-clean lenses by robust liquid-repellent nanotextures. This project aims to produce better performing self-cleaning lenses, which are less likely to get dirty and are easy to clean. It will develop water and oil repellent coatings with superior optical transparency and mechanical, solvent and UV stability for both hard coated and anti-reflection coated optical lenses. Engineering of stable, ultra-liquid repellent nanomaterials on transparent surfaces will create a foundation ....Next generation easy-clean lenses by robust liquid-repellent nanotextures. This project aims to produce better performing self-cleaning lenses, which are less likely to get dirty and are easy to clean. It will develop water and oil repellent coatings with superior optical transparency and mechanical, solvent and UV stability for both hard coated and anti-reflection coated optical lenses. Engineering of stable, ultra-liquid repellent nanomaterials on transparent surfaces will create a foundation of knowledge for the industrial development of the future generation of easy care coatings, with vast application potential.Read moreRead less
Fire-Retardant Composite Resins for Bushfire-Safe Wind Farm Infrastructures. This project aims to develop advanced fire-retardant composite resins for manufacturing bushfire-safe wind farm infrastructures. The innovation of the project is the development of a new class of low-cost, novel, highly effective fire retardants and their value-added fire-retardant composite resins with well-preserved physical properties. This will be achieved by understanding the composition-property relationship of fi ....Fire-Retardant Composite Resins for Bushfire-Safe Wind Farm Infrastructures. This project aims to develop advanced fire-retardant composite resins for manufacturing bushfire-safe wind farm infrastructures. The innovation of the project is the development of a new class of low-cost, novel, highly effective fire retardants and their value-added fire-retardant composite resins with well-preserved physical properties. This will be achieved by understanding the composition-property relationship of fire retardants and optimising their synthetic parameters. The project will help position Australia’s advanced composite manufacturing at the forefront of technology. It will also accelerate Australia’s energy transition to renewables by enabling bushfire-safe wind farm infrastructure.Read moreRead less
Doped alumina with tailored material properties for battery applications. This project aims to develop tailored alumina materials for lithium ion battery separators through a novel in-situ approach that will: (1) produce uniform doped alumina for improved safety, (2) target specific surface and bulk material properties to increase the overall performance, and (3) reduce manufacturing costs by integrating the process with new technology developed for the production of high purity alumina. Signifi ....Doped alumina with tailored material properties for battery applications. This project aims to develop tailored alumina materials for lithium ion battery separators through a novel in-situ approach that will: (1) produce uniform doped alumina for improved safety, (2) target specific surface and bulk material properties to increase the overall performance, and (3) reduce manufacturing costs by integrating the process with new technology developed for the production of high purity alumina. Significant advances are proposed for overcoming current manufacturing limitations of doped alumina. Building research capacity and knowledge in battery material manufacturing will benefit a range of industries across Australia, whilst providing new opportunities for growth in local communities.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