Effect of processing on microstructure of 'Biocrete' organo-mortar. 'Biocrete' is a novel organo-mortar whose composition differs substantially from conventional Portland cement based polymer mortars. It is a relatively new product with significant commercial potential because of its acid resistance and ease of application. However, the microstructure of this material is extremely complex and not well understood nor is the way the microstructure develops during the processing and application of ....Effect of processing on microstructure of 'Biocrete' organo-mortar. 'Biocrete' is a novel organo-mortar whose composition differs substantially from conventional Portland cement based polymer mortars. It is a relatively new product with significant commercial potential because of its acid resistance and ease of application. However, the microstructure of this material is extremely complex and not well understood nor is the way the microstructure develops during the processing and application of the material known. This project will use advanced materials characterisation methods to elucidate the microstructure and to quantify the effects of processing parameters on the microstructure. Such information is critical for further formulation and application development in important areas such as sewer relining.Read moreRead less
Fundamental understanding of the environmental factors essential for environmental assisted fracture (EAF) of cast magnesium alloys. This project proposes a combined theoretical and experimental approach to understand the key environmental factors causing EAF of commercial cast magnesium alloys. Rather than testing all possibilities, it is proposed to establish a mechanistic understanding for EAF, and to test and expand that understanding through key experiments. EAF is a particularly dangerous ....Fundamental understanding of the environmental factors essential for environmental assisted fracture (EAF) of cast magnesium alloys. This project proposes a combined theoretical and experimental approach to understand the key environmental factors causing EAF of commercial cast magnesium alloys. Rather than testing all possibilities, it is proposed to establish a mechanistic understanding for EAF, and to test and expand that understanding through key experiments. EAF is a particularly dangerous and complicated form of corrosion. Existing experience indicates that EAF incidence will increase as magnesium alloys are increasingly used in more challenging applications. The results and insights from this research will help to underpin a major new industry and industrial applications.Read moreRead less
Special Research Initiatives - Grant ID: SR0354805
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Research Network for Rehabilitation of Structures Using Advanced Materials and Frontier Technologies. There is an urgent need to rehabilitate existing structures that are considered inadequate in strength and serviceability. Frontier strengthening technologies (such as external post-tensioning and plate bonding) using conventional and advanced materials are being currently developed in Australia by different groups, but as yet not in a coordinated manner. The aim of this network is to bring tog ....Research Network for Rehabilitation of Structures Using Advanced Materials and Frontier Technologies. There is an urgent need to rehabilitate existing structures that are considered inadequate in strength and serviceability. Frontier strengthening technologies (such as external post-tensioning and plate bonding) using conventional and advanced materials are being currently developed in Australia by different groups, but as yet not in a coordinated manner. The aim of this network is to bring together a multi-disciplinary team with complementary strengths to provide an integrated solution for rehabilitation of structures. The core of the network focuses on design tools, linking the various technologies to provide appropriate rehabilitation and understanding of life cycle demands for major infrastructure.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100604
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Foam concrete using three-dimensional printing and nano-engineering. This project aims to design foam concrete. Foam concrete, made of air-voids and thin concrete films, has good thermal insulation/fire resistance and energy adsorption capacity but is weak. This project will develop a foam concrete via 3D printing to control air-void structures to achieve high strength and ductility and nano-engineering to improve the performance and durability of thin concrete films. It is expected that this hi ....Foam concrete using three-dimensional printing and nano-engineering. This project aims to design foam concrete. Foam concrete, made of air-voids and thin concrete films, has good thermal insulation/fire resistance and energy adsorption capacity but is weak. This project will develop a foam concrete via 3D printing to control air-void structures to achieve high strength and ductility and nano-engineering to improve the performance and durability of thin concrete films. It is expected that this high-performance foam concrete can be used as a load-bearing structural element to reduce construction costs. The project should discover chemical and physical mechanisms governing the resilience and sustainability of newly developed foam concrete.Read moreRead less
Multi-functional nano-modified cementitious materials for well cementing. By incorporating different nano-materials in well cements, this project aims to develop multi-functional cementitious materials with self-sensing properties and greater strength and durability under extreme conditions including high/low temperatures, high pressure and corrosive environments. The integrity and longevity of well cement are paramount for the safe, efficient, environmentally sustainable production of oil and n ....Multi-functional nano-modified cementitious materials for well cementing. By incorporating different nano-materials in well cements, this project aims to develop multi-functional cementitious materials with self-sensing properties and greater strength and durability under extreme conditions including high/low temperatures, high pressure and corrosive environments. The integrity and longevity of well cement are paramount for the safe, efficient, environmentally sustainable production of oil and natural gas resources. Cementing problems are the main factor contributing to incidents during drilling and completion of wells, necessitating costly remediation. It is expected that the novel cement developed in the project will produce safer wells with fewer (gas) environmental emission risks.Read moreRead less
Harnessing properties of liquid metals for future devices. This project aims to hybridise low toxicity liquid metal alloys of gallium with surface confined functional micro/nano materials and explore fundamental new fluidic and physical-chemistry phenomena. Liquid metals are an under-used group of materials, but their combination of flexibility, bestowed by their room temperature fluidity, and metallic properties means they demonstrate startling behaviour. The expected outcomes are new devices a ....Harnessing properties of liquid metals for future devices. This project aims to hybridise low toxicity liquid metal alloys of gallium with surface confined functional micro/nano materials and explore fundamental new fluidic and physical-chemistry phenomena. Liquid metals are an under-used group of materials, but their combination of flexibility, bestowed by their room temperature fluidity, and metallic properties means they demonstrate startling behaviour. The expected outcomes are new devices and systems such as reconfigurable and highly efficient actuators/generators, catalysts, sensors, and electronic and optical components.Read moreRead less
Green Machining of Powder Metallurgy Based Aluminium Composites. This project will initiate and establish a collaborative research program between Professor Wojciech Z. Misiolek of Lehigh University (Bethlehem, PA, USA) and Professor Graham Schaffer at The University of Queensland. Professor Misiolek will spend an extended six month period at The University of Queensland. The specific aim of the project is to develop a method to machine aluminium composites in the green, or unsintered, state. Th ....Green Machining of Powder Metallurgy Based Aluminium Composites. This project will initiate and establish a collaborative research program between Professor Wojciech Z. Misiolek of Lehigh University (Bethlehem, PA, USA) and Professor Graham Schaffer at The University of Queensland. Professor Misiolek will spend an extended six month period at The University of Queensland. The specific aim of the project is to develop a method to machine aluminium composites in the green, or unsintered, state. This will overcome a major impediment to the wider utilisation of aluminium matrix composites, which have an attractive combination of properties but cannot be formed into complex shapes using conventional processing methodologies.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453480
Funder
Australian Research Council
Funding Amount
$236,899.00
Summary
Nanostructured Polymer Processing Network. The Nanostructured Polymer Processing Network will promote the understanding and manipulation of the processing of novel nanostructured plastic materials. High technology, online polymer processing equipment will be sought that will enable the design of nanostructured polymers via a range of techniques including insitu polymerisation, nanocomposites and polymer blending which are ideal for designing high value nanostructured polymers that are tailored f ....Nanostructured Polymer Processing Network. The Nanostructured Polymer Processing Network will promote the understanding and manipulation of the processing of novel nanostructured plastic materials. High technology, online polymer processing equipment will be sought that will enable the design of nanostructured polymers via a range of techniques including insitu polymerisation, nanocomposites and polymer blending which are ideal for designing high value nanostructured polymers that are tailored for high performance applications. The equipment in this proposal, when combined with existing leading edge polymer characterisation and analysis equipment, will provide a Network with international state-of-the-art equipment that will fast track the success of integrated research projects across the sites.Read moreRead less
Computer Modelling of the Morphology and Crystallography of Diffusion-controlled Phase Transformations. An analytical, phenomenological version of the successful "edge-to edge" matching approach to the morphology and crystallography of diffusion-controlled phase transformations will be developed. This will be incorporated in a Windows based computer program that can predict the essential features of precipitation (orientation relationships, habit planes, morphology and interface structure), fro ....Computer Modelling of the Morphology and Crystallography of Diffusion-controlled Phase Transformations. An analytical, phenomenological version of the successful "edge-to edge" matching approach to the morphology and crystallography of diffusion-controlled phase transformations will be developed. This will be incorporated in a Windows based computer program that can predict the essential features of precipitation (orientation relationships, habit planes, morphology and interface structure), from readily available input data for the two phases involved. It will provide a fuller understanding of diffusion-controlled phase transformations and the computer simulation will assist in the development of improved precipitation hardening alloys. In addition, a database of crystallographic data for typical metallic materials will be established in the project.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882347
Funder
Australian Research Council
Funding Amount
$340,000.00
Summary
High field magnet for materials processing and characterisation. The proposed infrastructure project will bring many Australian-based researchers together to create a completely new niche of materials processing research. Such a facility will be the first of its kind in Australia. This facility will be located in Australia and thus the time required to process and characterize materials will be significantly reduced without a need to send them overseas. As a consequence of the proposed collabora ....High field magnet for materials processing and characterisation. The proposed infrastructure project will bring many Australian-based researchers together to create a completely new niche of materials processing research. Such a facility will be the first of its kind in Australia. This facility will be located in Australia and thus the time required to process and characterize materials will be significantly reduced without a need to send them overseas. As a consequence of the proposed collaboration, a large number of high quality papers and patents are expected. The facility will increase Australia's position in the field of advanced materials processing and will also provide new ideas and concepts, which will be used in practical applications.Read moreRead less