Characterization of mechanical behaviour of TiO2 nanotube thin films. Vertically aligned titanium oxide (TiO2) nanotube arrays have demonstrated remarkable properties for application in dyesensitised solar cell, photocatalysis, self-cleaning coating, purification of pollutants and orthopaedic implants. More excitingly, their architecture and dimensions can be precisely controlled using anodisation of titanium (Ti), creating considerable scientific interest and practical importance. This project ....Characterization of mechanical behaviour of TiO2 nanotube thin films. Vertically aligned titanium oxide (TiO2) nanotube arrays have demonstrated remarkable properties for application in dyesensitised solar cell, photocatalysis, self-cleaning coating, purification of pollutants and orthopaedic implants. More excitingly, their architecture and dimensions can be precisely controlled using anodisation of titanium (Ti), creating considerable scientific interest and practical importance. This project aims to develop novel techniques for determining the mechanical behaviour of TiO2 nanotube arrays and its dependence on crystal structure and geometrical parameters. The outcomes are expected to provide solutions to development of robust TiO2 and other nanotube arrays for broad applications in sustainable energy and tissue engineering.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120100055
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Controlling light with nonlinear effects in silicon nanocrystals. The project will help to promote in Australia the novel field of silicon nanophotonics, which is currently one of the most explored disciplines within the field of integrated optics. It will introduce innovative concepts for superior light control, which will keep Australia at the forefront of international research and frontier technologies.
Discovery Early Career Researcher Award - Grant ID: DE150101755
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Regulation of cell reprogramming to pluripotency by complex topographies. This project aims to use nanotopography approaches to improve the efficiency of generating induced Pluripotent Stem Cells (iPSCs) by changing cell behaviour at biomaterial surfaces. The significance is that iPSCs have enormous potential in stem cell therapy, regenerative medicine, and disease-specific treatment, with the potential to replace other stem cell types. The expected outcomes are that cellular reprogramming proce ....Regulation of cell reprogramming to pluripotency by complex topographies. This project aims to use nanotopography approaches to improve the efficiency of generating induced Pluripotent Stem Cells (iPSCs) by changing cell behaviour at biomaterial surfaces. The significance is that iPSCs have enormous potential in stem cell therapy, regenerative medicine, and disease-specific treatment, with the potential to replace other stem cell types. The expected outcomes are that cellular reprogramming process for iPSCs generation will be improved and the canonical reprogramming factors might be reduced using surface nanotopographies of self-assembled colloidal crystals. The benefits are the promotion of productivity, the reduction of costs, and the application of iPSC derivatives, aimed at future clinical applications.Read moreRead less
Investigation of capillarity and photonics for inexpensive and accurate electrophoresis instrumentation. Capillary electrophoresis promises sensitive detection of specific proteins in blood which can be correlated to heart diseases. This project aims to research new ways to do this simply and cheaply so that tests can be done at rural places to derive maximum benefit from fast online medical consultation without setting up costly laboratories.
Versatile dosimetry systems for radiotherapy and industrial applications: novel storage phosphor and associated reader technologies. Radiotherapy is an important procedure in the treatment of cancer, and it is essential that the radiation dosage can be accurately measured. This project will develop technology which will enable us to monitor radiation dosage in real time and very accurately. This will be of importance in medical science and also for industrial applications.
Engineered interlayers of bio-retardant and nano-reinforcement on polymers. This project will address the important need for a highly effective lightweight coating. Different interlayers of bio-retardants derive from organic compounds and two-dimensional sheet-like nanomaterials are fabricated to enhance the charring, thermal barrier and flammability resistance. Molecular dynamics are adopted to deliver more targeted fabrication to achieve increased efficacy of the engineered interlayers and pro ....Engineered interlayers of bio-retardant and nano-reinforcement on polymers. This project will address the important need for a highly effective lightweight coating. Different interlayers of bio-retardants derive from organic compounds and two-dimensional sheet-like nanomaterials are fabricated to enhance the charring, thermal barrier and flammability resistance. Molecular dynamics are adopted to deliver more targeted fabrication to achieve increased efficacy of the engineered interlayers and provide important insights on the combustibility of polymers undergoing mass diffusivity, thermal diffusion and oxidation process at high temperatures. Expected outcomes of the project are lightweight coated polymers possessing elevated resistance to fire with a significant reduction of toxic gas emissions and smoke releases. Read moreRead less
A multiplex microscope platform to define molecular events in fluid systems. This project aims to develop a novel microscopy platform that will enable the visualisation and quantification of molecular events occurring under fluid shear stress. The project will generate new knowledge in platelet biology that will allow characterisation and prediction of key molecular and morphological changes occurring across a blood thrombus under flowing conditions as found in the blood vessels. These new tools ....A multiplex microscope platform to define molecular events in fluid systems. This project aims to develop a novel microscopy platform that will enable the visualisation and quantification of molecular events occurring under fluid shear stress. The project will generate new knowledge in platelet biology that will allow characterisation and prediction of key molecular and morphological changes occurring across a blood thrombus under flowing conditions as found in the blood vessels. These new tools and the imaging platform will have applications for researchers wishing to visualise small and rapid molecular events in four dimensions (length, width, height and across time) under fluid shear stress, which is applicable across a range of industries. The project expects to deliver the next generation of intravital microscopes that can visualise and quantify events in a challenging flow environment.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100909
Funder
Australian Research Council
Funding Amount
$425,523.00
Summary
3D micro-bioprinting: acoustic actuation to shape single-cell organization. This project aims to develop an innovative cell-printing technology to replicate the microscale cell structure found in native human and animal tissues. This is based on an interdisciplinary concept that combines ultra-high frequency acoustic cell manipulation with 3D stereolithography printing, and will examine acoustic waveguide element design and their topological optimisation. In contrast to current 3D printing metho ....3D micro-bioprinting: acoustic actuation to shape single-cell organization. This project aims to develop an innovative cell-printing technology to replicate the microscale cell structure found in native human and animal tissues. This is based on an interdisciplinary concept that combines ultra-high frequency acoustic cell manipulation with 3D stereolithography printing, and will examine acoustic waveguide element design and their topological optimisation. In contrast to current 3D printing methods that are not suitable for precisely integrating microscale elements in the printing process, this work will open up the range of materials, including functional human tissues, that can be printed.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100174
Funder
Australian Research Council
Funding Amount
$193,000.00
Summary
Acoustic levitation facility for high pressure multiphase systems research. This project aims to create a specialised acoustic levitation facility that delivers precise control of a suspended particle/droplet/bubble within a high pressure continuous phase, and simultaneous measurement of multiple bulk and interfacial properties. Acoustic levitation enables container-less experiments, offering opportunities for applied engineering and fundamental science. This acoustic levitation system will be i ....Acoustic levitation facility for high pressure multiphase systems research. This project aims to create a specialised acoustic levitation facility that delivers precise control of a suspended particle/droplet/bubble within a high pressure continuous phase, and simultaneous measurement of multiple bulk and interfacial properties. Acoustic levitation enables container-less experiments, offering opportunities for applied engineering and fundamental science. This acoustic levitation system will be integrated with a specialised Raman imaging microscope to study crystallisation, mass transfer and molecular exchange, in application areas including energy transport, carbon capture and storage, and protein nucleation. This project is expected to open new avenues in engineering, chemistry and physics.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH150100003
Funder
Australian Research Council
Funding Amount
$2,611,346.00
Summary
ARC Research Hub for Graphene Enabled Industry Transformation. ARC Research Hub for Graphene Enabled Industry Transformation. This research hub aims to provide the advanced materials industry with innovative solutions to tackle critical and complex challenges of national significance. The hub intends to leverage substantial existing and new investments to overcome fundamental scientific barriers and develop fit-for-purpose graphene products with and for its partners. Advanced materials, particul ....ARC Research Hub for Graphene Enabled Industry Transformation. ARC Research Hub for Graphene Enabled Industry Transformation. This research hub aims to provide the advanced materials industry with innovative solutions to tackle critical and complex challenges of national significance. The hub intends to leverage substantial existing and new investments to overcome fundamental scientific barriers and develop fit-for-purpose graphene products with and for its partners. Advanced materials, particularly graphene, are now considered promising for maintaining competitive advantages for industrial transformational progress; and advanced industries to drive prosperity where innovation underpins business to thrive globally. The anticipated impacts are long-term economic prosperity and growth.Read moreRead less