Development of three-dimensional printing conductive concrete for electromagnetic pulse shielding. This project aims to develop innovative methods for the use of conductive concrete as a building material with an electromagnetic pulse (EMP) shielding property. Three dimensional printing of conductive concrete will present an innovative and promising technique in real-life construction practices when structures are needed for facilities and infrastructure employed for critical services such as mi ....Development of three-dimensional printing conductive concrete for electromagnetic pulse shielding. This project aims to develop innovative methods for the use of conductive concrete as a building material with an electromagnetic pulse (EMP) shielding property. Three dimensional printing of conductive concrete will present an innovative and promising technique in real-life construction practices when structures are needed for facilities and infrastructure employed for critical services such as military or financial infrastructures. The project will create new revenue streams for cement and concrete industry as well as empower the workforce with cutting-edge skills. The newly developed materials and technology will lead to protection of national facilities and infrastructure.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
Development of nano reinforced concrete using boron nitride nanosheets. This project seeks to develop high-performance concrete materials by exploiting emerging nanotechnology. It plans to adopt emerging nanotechnology involving hexagonal boron nitride nanosheets and advanced micro-computer tomography instrumentation to transform conventional concrete into one that is stronger and more durable in extreme environmental conditions. It also plans to use sophisticated modelling techniques including ....Development of nano reinforced concrete using boron nitride nanosheets. This project seeks to develop high-performance concrete materials by exploiting emerging nanotechnology. It plans to adopt emerging nanotechnology involving hexagonal boron nitride nanosheets and advanced micro-computer tomography instrumentation to transform conventional concrete into one that is stronger and more durable in extreme environmental conditions. It also plans to use sophisticated modelling techniques including molecular dynamics simulations as well as microplane models to analyse the effect of nanofillers. The findings may drive advances in cement hydration, nanotechnology, concrete technology and blast, impact and fire engineering.Read moreRead less
Determination of the Properties of Hyper-Elastic Materials by Deep Indentation. We seek to develop the scientific basis for the interpretation of the results of "deep" indentation testing of non-linear elastic (hyper-elastic) materials. Simple tests (such as indentation) produce complex strain fields. Interpretation of the resulting data in terms of stiffness, for example, requires a complex model of the deformation process that can be utilised to link the observed behaviour to the basic prope ....Determination of the Properties of Hyper-Elastic Materials by Deep Indentation. We seek to develop the scientific basis for the interpretation of the results of "deep" indentation testing of non-linear elastic (hyper-elastic) materials. Simple tests (such as indentation) produce complex strain fields. Interpretation of the resulting data in terms of stiffness, for example, requires a complex model of the deformation process that can be utilised to link the observed behaviour to the basic properties of interest. This project is dedicated to an understanding of the complex deformation associated with large strain indentation of hyper-elastic materials and structures, development of finite element based models for this deformation and creation of techniques for interpretation of the results of such indentation tests.Read moreRead less
Testing, modelling and engineering applications of topologically interlocking structures. The CI and his international collaborator have recently proposed a new principle of design of materials and structures based on topological interlocking of constituent elements. Elements of simple shape, such as tetrahedra, are assembled in structures that keep their integrity without any binder or connectors. Unusual properties, such as high fracture toughness and damage tolerance were found. The project a ....Testing, modelling and engineering applications of topologically interlocking structures. The CI and his international collaborator have recently proposed a new principle of design of materials and structures based on topological interlocking of constituent elements. Elements of simple shape, such as tetrahedra, are assembled in structures that keep their integrity without any binder or connectors. Unusual properties, such as high fracture toughness and damage tolerance were found. The project aims at investigating the mechanical and acoustic properties of the newly discovered interlockable geometries (cubes, octahedra, dodecahedra and icosahedra) and identifying the areas of application. The project will promote the international leading role of the collaborating institutions in this novel field.Read moreRead less
A NEW CONCEPT IN DESIGN OF MATERIALS AND STRUCTURES BASED ON TOPOLOGICALLY INTERLOCKED ELEMENTS. The project aims to develop a new concept in materials design based on assemblies of interlocked elements. Interlocking is achieved topologically by special arrangements of blocks without connectors. Such assemblies can form structures possessing special mechanical properties and serve as load-bearing skeletons in composites with a binder phase providing desired functional properties. Various types o ....A NEW CONCEPT IN DESIGN OF MATERIALS AND STRUCTURES BASED ON TOPOLOGICALLY INTERLOCKED ELEMENTS. The project aims to develop a new concept in materials design based on assemblies of interlocked elements. Interlocking is achieved topologically by special arrangements of blocks without connectors. Such assemblies can form structures possessing special mechanical properties and serve as load-bearing skeletons in composites with a binder phase providing desired functional properties. Various types of interlocked assemblies will be modelled, produced and tested to determine their mechanical and acoustic properties. A range of experimental techniques tailored for these unusual assemblies will be employed. The expected outcome will be the implementation of the new design principle in multifunctional materials and structures.Read moreRead less
Damage micromechanisms in alumina hybrid bilayers with graded interfaces. This project proposes a new design concept for high performance alumina hybrids with graded interfaces. The key to this process is the incorporation of thin graded interfaces between an outer homogeneous alumina layer for strength, hardness and wear resistance, and an inner heterogeneous alumina hybrid layer for damage tolerance. The project will explore unresolved issues concerning the effect of graded interfaces on the f ....Damage micromechanisms in alumina hybrid bilayers with graded interfaces. This project proposes a new design concept for high performance alumina hybrids with graded interfaces. The key to this process is the incorporation of thin graded interfaces between an outer homogeneous alumina layer for strength, hardness and wear resistance, and an inner heterogeneous alumina hybrid layer for damage tolerance. The project will explore unresolved issues concerning the effect of graded interfaces on the failure micromechanisms. Advances in this area will provide new strategy or insights for designing novel next generation layered materials.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101795
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
Exceptional properties by design – NiTi vision. The fundamental leaps in new technologies occur with improvements in the materials with which they are made. Until recently high performance metallic composite design had hit a 20 year blockage in nanocomposite design. The solution, a Nickel, Titanium and Niobium (NiTi-Nb) nanowire composite has been heralded as an era of new possibilities in materials design. This project aims to advance high performance metallic composite design by investigating ....Exceptional properties by design – NiTi vision. The fundamental leaps in new technologies occur with improvements in the materials with which they are made. Until recently high performance metallic composite design had hit a 20 year blockage in nanocomposite design. The solution, a Nickel, Titanium and Niobium (NiTi-Nb) nanowire composite has been heralded as an era of new possibilities in materials design. This project aims to advance high performance metallic composite design by investigating the mechanisms of exceptionally large elastic strains achieved in nanowires embedded in a phase-transforming metallic matrix (i.e. NiTi). An understanding of this high performance nanocomposite design has broad application in medicine and engineering.Read moreRead less
CO2 Utilisation for Energy Storage. This project aims to develop a novel technology that can convert carbon dioxide into useful products while storing intermittent renewable energy as green stable chemical energy. The project plans to focus on the development of a robust cathode for the conversion of carbon dioxide with optimum physical and chemical structure to achieve long-term stable performance. This technology would make a significant contribution to increasing the proportion of renewable e ....CO2 Utilisation for Energy Storage. This project aims to develop a novel technology that can convert carbon dioxide into useful products while storing intermittent renewable energy as green stable chemical energy. The project plans to focus on the development of a robust cathode for the conversion of carbon dioxide with optimum physical and chemical structure to achieve long-term stable performance. This technology would make a significant contribution to increasing the proportion of renewable energy in our energy supply and reducing our carbon dioxide emissions.Read moreRead less