Assessment of structural integrity and deterioration of masonry walls. Brickwork for housing and medium-rise buildings is a traditional material, also much used for modern construction, with aesthetic appeal and modest cost. However, building regulators and others are increasingly concerned about evidence of slow building deterioration, particularly of older buildings. This increases public safety risks, even under normal conditions and more so under high winds or earthquake-induced ground-shaki ....Assessment of structural integrity and deterioration of masonry walls. Brickwork for housing and medium-rise buildings is a traditional material, also much used for modern construction, with aesthetic appeal and modest cost. However, building regulators and others are increasingly concerned about evidence of slow building deterioration, particularly of older buildings. This increases public safety risks, even under normal conditions and more so under high winds or earthquake-induced ground-shaking. This project will help address this issue. It will obtain unbiased evidence of typical masonry building deterioration. It will couple this with mathematical modelling and state-of-the-art non-destructive visual and dynamic techniques to develop tools for making fast, low-cost practical building risk assessments.Read moreRead less
Advancing the Australian specialty alloy processing capability. This project aims to advance Australia’s specialty alloy processing capability by developing novel processing routes to overcome current bottlenecks that prevent supply meeting demand. New knowledge will be generated on alternative means of the processing of Rene 41, a Nickel-based superalloy with limited formability through a comprehensive experimental and modelling-based research program. Rene 41 is strategically important for man ....Advancing the Australian specialty alloy processing capability. This project aims to advance Australia’s specialty alloy processing capability by developing novel processing routes to overcome current bottlenecks that prevent supply meeting demand. New knowledge will be generated on alternative means of the processing of Rene 41, a Nickel-based superalloy with limited formability through a comprehensive experimental and modelling-based research program. Rene 41 is strategically important for manufacturing next generation turbofan engines. The expected outcome is the identification of innovative processing routes to provide stronger, defect-free specialty alloys for aerospace applications, vital to Australia’s advanced manufacturing.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100124
Funder
Australian Research Council
Funding Amount
$538,590.00
Summary
An Advanced Ultrafast Laser Spectroscopy Facility in Queensland. The project aims to establish a world-class ultrafast laser spectroscopy facility to investigate how molecules interact with visible or ultraviolet light. Light-matter interactions are key to energy generation in nature through photosynthesis as well as everyday technologies including optical communications and displays. This project expects to generate new knowledge in on how light interacts with matter at the molecular level. Exp ....An Advanced Ultrafast Laser Spectroscopy Facility in Queensland. The project aims to establish a world-class ultrafast laser spectroscopy facility to investigate how molecules interact with visible or ultraviolet light. Light-matter interactions are key to energy generation in nature through photosynthesis as well as everyday technologies including optical communications and displays. This project expects to generate new knowledge in on how light interacts with matter at the molecular level. Expected outcomes of the ultrafast spectroscopic measurements will be understanding the fate of light absorbed by or generated in different materials. Application of the knowledge gained will enable the design of materials for more efficient technologies such as solar cells, lighting, and sensors.Read moreRead less
Fill it, Squeeze it, Crush it: Extreme Gas Uptake in Microporous Materials . Porous materials have the potential to be used as exceptional carbon capture materials, as well as for trapping and releasing other useful gases, such as those used in medical applications. They work, because they contain small holes where these gases can be trapped. Unfortunately, finding gas inside these holes experimentally is incredibly difficult, making it challenging to make better porous materials. In this pro ....Fill it, Squeeze it, Crush it: Extreme Gas Uptake in Microporous Materials . Porous materials have the potential to be used as exceptional carbon capture materials, as well as for trapping and releasing other useful gases, such as those used in medical applications. They work, because they contain small holes where these gases can be trapped. Unfortunately, finding gas inside these holes experimentally is incredibly difficult, making it challenging to make better porous materials. In this project, I will use extreme pressures to saturate these holes with gas molecules, allowing us to ‘see’ them. Not only will this mean that better porous materials can be designed and made, but will provide a unique approach to storing and trapping gases to be used in a variety of applications, from the energy to medical sectors.Read moreRead less
Developing innovative concrete composites by upscaling material properties. This project aims to develop an upscaling process to correlate micro-nano properties of engineering materials to their comprehensive physicochemical properties based on systematic mechanical and statistical analysis approaches and nanoindentation technology. The process will enable assessing material mechanical and viscoelastic properties at a microscale level thus will generate a new knowledge in structural engineering ....Developing innovative concrete composites by upscaling material properties. This project aims to develop an upscaling process to correlate micro-nano properties of engineering materials to their comprehensive physicochemical properties based on systematic mechanical and statistical analysis approaches and nanoindentation technology. The process will enable assessing material mechanical and viscoelastic properties at a microscale level thus will generate a new knowledge in structural engineering discipline including health monitoring, assessment of existing structures, historical buildings, and strengthening and repairing materials in structures. The outcomes are a multiscale link model for upscaling material properties and a development of innovative reinforced concrete composites which are cost-effective and efficient.Read moreRead less
Multi-hazard resilient hybrid modular structures. This project aims to develop the next generation of multi-hazard resilient modular construction methods for efficient, affordable and sustainable buildings. New demountable modular connections will be developed and the response of hybrid modular buildings to multiple hazards such as wind, earthquake, blast and impact will be investigated through a combination of experimental, numerical, and analytical studies. The project will develop knowledge o ....Multi-hazard resilient hybrid modular structures. This project aims to develop the next generation of multi-hazard resilient modular construction methods for efficient, affordable and sustainable buildings. New demountable modular connections will be developed and the response of hybrid modular buildings to multiple hazards such as wind, earthquake, blast and impact will be investigated through a combination of experimental, numerical, and analytical studies. The project will develop knowledge of the structural behaviour of hybrid modular buildings, and expects to deliver design methods and robust simplified models for building design purposes. This project will advance construction techniques and practices for resilient hybrid modular buildings.Read moreRead less
Development of Novel Metaconcrete to Resist Impulsive Loads. This project aims to develop innovative metaconcrete for structural protection by utilising the concept of phononic crystals and metamaterials which has been recently developed by physicists. Traditional construction materials are used in new structural forms to mitigate dynamic loading effects by exploiting the unique characteristics of the proposed metaconcrete. Theoretical, numerical and experimental methods will be used to derive t ....Development of Novel Metaconcrete to Resist Impulsive Loads. This project aims to develop innovative metaconcrete for structural protection by utilising the concept of phononic crystals and metamaterials which has been recently developed by physicists. Traditional construction materials are used in new structural forms to mitigate dynamic loading effects by exploiting the unique characteristics of the proposed metaconcrete. Theoretical, numerical and experimental methods will be used to derive the best performing metaconcrete and verify its static and dynamic load resistant capacities. The expected outcomes of the project will lead to innovative extreme-loading resistant designs and provide significant benefit to the Australian construction industry, general public and economy.Read moreRead less
Sustainable and robust Australian Ni-based superalloy manufacturing. This project aims to solve challenges related to microstructural defect formation in the manufacturing of a critical Ni-based superalloy. It will generate new knowledge on its microstructure evolution and defect origin via a combined experimental and computational approach. Expected outcomes are advanced manufacturing routes with higher yield of defect free materials, using more scrap as input. This will enable robust and susta ....Sustainable and robust Australian Ni-based superalloy manufacturing. This project aims to solve challenges related to microstructural defect formation in the manufacturing of a critical Ni-based superalloy. It will generate new knowledge on its microstructure evolution and defect origin via a combined experimental and computational approach. Expected outcomes are advanced manufacturing routes with higher yield of defect free materials, using more scrap as input. This will enable robust and sustainable alloy manufacturing for power generation, defence, and aerospace industries. Commercial benefits are opportunities to domestically source alloys with reduced dependency on international trade. Environmental and societal benefits include lower emissions due to better mechanical design and workforce training.Read moreRead less