Using 3D printing technology to develop architecturally-controlled synthetic bone substitutes. With the ageing population, there is increasing demand for synthetic materials that can regenerate bone. However, purely synthetic bone-substitute biomaterials cannot regenerate large bone defects in weight-bearing conditions due to their fragility. This project aims to develop a customisable, biodegradable, biocompatible and mechanically strong and tough scaffold that overcomes this long-standing prob ....Using 3D printing technology to develop architecturally-controlled synthetic bone substitutes. With the ageing population, there is increasing demand for synthetic materials that can regenerate bone. However, purely synthetic bone-substitute biomaterials cannot regenerate large bone defects in weight-bearing conditions due to their fragility. This project aims to develop a customisable, biodegradable, biocompatible and mechanically strong and tough scaffold that overcomes this long-standing problem. The project aims to achieve this by applying an innovative combination of cutting-edge 3D printing technology, advanced computational modelling and design techniques to produce a next-generation bioceramic scaffold with optimised architecture. This approach aims also to enable the possibility of producing custom-made implants for individual requirements.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100150
Funder
Australian Research Council
Funding Amount
$595,280.00
Summary
Advanced multifunctional photoelectron spectroscopy platform. This project aims to establish a new integrated facility that will allow researchers to characterise the surface structure and electronic properties of materials, which is essential for a complete understanding of their functionality. The development of the next generation of electronic, optical, and biomedical devices requires new materials with properties optimised for the particular application. This facility, to be housed in state ....Advanced multifunctional photoelectron spectroscopy platform. This project aims to establish a new integrated facility that will allow researchers to characterise the surface structure and electronic properties of materials, which is essential for a complete understanding of their functionality. The development of the next generation of electronic, optical, and biomedical devices requires new materials with properties optimised for the particular application. This facility, to be housed in state-of-the-art laboratories and managed as an open access resource, will meet the needs of a large number of innovative projects and enable advances in many fields including electronics, nanotechnology, solar energy, biotechnology and advanced materials.Read moreRead less
Using extreme conditions to synthesise new materials. This project aims to synthesise useful materials from non-crystalline light element precursors. Boron, carbon and nitrogen are the hardest known solids, and their ability to form many kinds of chemical bonds offers opportunities for attractive new materials. This project will apply high pressures and temperatures to non-crystalline precursor materials to access previously unobtainable synthesis conditions. This project will create strong and ....Using extreme conditions to synthesise new materials. This project aims to synthesise useful materials from non-crystalline light element precursors. Boron, carbon and nitrogen are the hardest known solids, and their ability to form many kinds of chemical bonds offers opportunities for attractive new materials. This project will apply high pressures and temperatures to non-crystalline precursor materials to access previously unobtainable synthesis conditions. This project will create strong and hard materials with tuneable optical and electronic properties. The expected outcome is new light materials that emit and detect light in the far ultraviolet for biological imaging and tough materials with low friction needed for motors and regenerative technologies.Read moreRead less
Mass transport in high entropy alloys. This project aims to understand mass transport in high entropy alloys. Alloys of 5 to 13 components have technologically attractive mechanical properties. A knowledge of mass transport could control their stabilities and optimise their properties. This project will develop an atomistic theory and a phenomenological method for rapidly performing experiments, and experiment on two key high entropy alloys. The outcome of this research will be an in-depth under ....Mass transport in high entropy alloys. This project aims to understand mass transport in high entropy alloys. Alloys of 5 to 13 components have technologically attractive mechanical properties. A knowledge of mass transport could control their stabilities and optimise their properties. This project will develop an atomistic theory and a phenomenological method for rapidly performing experiments, and experiment on two key high entropy alloys. The outcome of this research will be an in-depth understanding of mass transport that is expected to fast-track these alloys to commercial uptake.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100072
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
Facility for exploring light-matter interactions in space, time and energy. This project aims to create a readily accessible facility consisting of a suite of tools to study light-matter interactions in materials, molecules and biological systems. Understanding light-matter interactions offers insight into the properties of nano- and biomaterials. The project intends to combine local probes and pump-probe spectroscopy methods for studying nanoscale femtosecond dynamics. It will be accessible to ....Facility for exploring light-matter interactions in space, time and energy. This project aims to create a readily accessible facility consisting of a suite of tools to study light-matter interactions in materials, molecules and biological systems. Understanding light-matter interactions offers insight into the properties of nano- and biomaterials. The project intends to combine local probes and pump-probe spectroscopy methods for studying nanoscale femtosecond dynamics. It will be accessible to a broad user base, cementing Australia’s leadership in ultrafast spectroscopy techniques and nano/bio-materials. The facility will provide a window to the quantum nanoworld, with potential for developing new energy efficient light sources, light-harvesting systems and sensors.Read moreRead less
Systems engineering approach to nanostructuring porous electrodes for compact capacitive energy storage. This project will develop a new systems engineering approach to fabricating porous yet densely packed electrodes with high ion-accessible surface area and low ion transport impedance. This will lead to new-generation compact electrochemical capacitive energy storage systems that can combine high energy density, fast charging/discharging rate and long cycle life. The success of this project wi ....Systems engineering approach to nanostructuring porous electrodes for compact capacitive energy storage. This project will develop a new systems engineering approach to fabricating porous yet densely packed electrodes with high ion-accessible surface area and low ion transport impedance. This will lead to new-generation compact electrochemical capacitive energy storage systems that can combine high energy density, fast charging/discharging rate and long cycle life. The success of this project will facilitate future large-scale adoption of renewable energy and many other new emerging technologies such as portable/wearable electronics, electric vehicles, and energy regeneration systems.Read moreRead less
Sensory Neuronal Pathways From The Lower Genital Tract Of Females
Funder
National Health and Medical Research Council
Funding Amount
$397,224.00
Summary
Many women experience severe debilitating pain upon normally innocuous contact with their genitalia. The causes of this pain are unknown. Therefore, this project will use a suite of sophisticated microscopic and electrical recording techniques to identify the neural pathways that transmit sensation, including pain, from the female lower genital tract. Our new data will help create a rational basis for understanding and treating the physical basis of genital pain in women.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100116
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
Facilities of thermophysical characterisations at nanometre scale for development of advanced materials, energy technologies and biomedical components. Australia's energy, mining, metallurgical, defence, pharmaceutical and biomedical industries are spearheading the advancement of technologies in the global competitive market. They are the engines of Australian economic strength. Future progress of these industries will be largely driven by advances in materials. The installation of the propose ....Facilities of thermophysical characterisations at nanometre scale for development of advanced materials, energy technologies and biomedical components. Australia's energy, mining, metallurgical, defence, pharmaceutical and biomedical industries are spearheading the advancement of technologies in the global competitive market. They are the engines of Australian economic strength. Future progress of these industries will be largely driven by advances in materials. The installation of the proposed facilities will add a new dimension to high-level research performance and significantly enhance the capability for characterisation of various forms of materials and biomedical components in Australia. The continual development of advanced materials and energy technology will potentially provide a sustainable means for meeting the increasing global challenge for the industries.Read moreRead less