Metal-air batteries with improved rate capability and safety for hearing applications. Hearing impairment affects on average 20% of the adult population in western society, with the impact being as high as 50% in older adults. Effective hearing devices require a significant amount of power, supplied by a battery, to support their function. Current batteries require very frequent replacement and represent a significant impediment to advances in the technology. This project will develop improved ....Metal-air batteries with improved rate capability and safety for hearing applications. Hearing impairment affects on average 20% of the adult population in western society, with the impact being as high as 50% in older adults. Effective hearing devices require a significant amount of power, supplied by a battery, to support their function. Current batteries require very frequent replacement and represent a significant impediment to advances in the technology. This project will develop improved energy and power density batteries which will lead to immediate implementation of more powerful signal processing algorithms, making hearing aids much more effective and appealing to the user. This, in turn, will improve recipient compliance and thus the quality of life for those with severe hearing impairment. Read moreRead less
Development of high-performance lead-free piezoelectric superlattices for environmentally-friendly and biocompatible piezoelectric micromachined ultrasonic transducers (pMUTs) applications. This program is aimed at development of environmentally friendly and biocompatible lead-free piezoelectric thin films and superlattices for the potential applications in pMUTs. The expected outcome includes deposition of BNT and BZT-based thin films and superlattices, and enhancement of their physical propert ....Development of high-performance lead-free piezoelectric superlattices for environmentally-friendly and biocompatible piezoelectric micromachined ultrasonic transducers (pMUTs) applications. This program is aimed at development of environmentally friendly and biocompatible lead-free piezoelectric thin films and superlattices for the potential applications in pMUTs. The expected outcome includes deposition of BNT and BZT-based thin films and superlattices, and enhancement of their physical properties by strain and interface engineering.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100311
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Multidirectional stretchable and wearable tactile sensors. This project aims to establish a new platform for multidirectional wearable tactile sensors with high sensitivity and stretchability based on rational material designs and structural engineering. Wearable tactile sensors with multidirectional force-sensing capabilities are of great importance in robotics, prosthetics, and rehabilitation devices. This novel form of tactile sensing will be developed through fundamental research into the wo ....Multidirectional stretchable and wearable tactile sensors. This project aims to establish a new platform for multidirectional wearable tactile sensors with high sensitivity and stretchability based on rational material designs and structural engineering. Wearable tactile sensors with multidirectional force-sensing capabilities are of great importance in robotics, prosthetics, and rehabilitation devices. This novel form of tactile sensing will be developed through fundamental research into the working mechanism of directional sensors to enable detection of different force intensities. Combined with new device fabrication techniques, and innovative material structural engineering, the expected outcome is a new multidirectional tactile sensor system with high sensitivity and stretchability.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100284
Funder
Australian Research Council
Funding Amount
$359,008.00
Summary
Stretchable strain sensors based on three-dimensional structured nano-carbon. This project aims to develop a class of stretchable strain sensors based on three-dimensionally (3D) structured carbon nanomaterials for wearable devices. The project plans to design and fabricate 3D-structured carbon with structures and physical properties for developing nanocomposites for strain sensing applications. The expected outcome is wearable sensors capable of monitoring human movements with potential applica ....Stretchable strain sensors based on three-dimensional structured nano-carbon. This project aims to develop a class of stretchable strain sensors based on three-dimensionally (3D) structured carbon nanomaterials for wearable devices. The project plans to design and fabricate 3D-structured carbon with structures and physical properties for developing nanocomposites for strain sensing applications. The expected outcome is wearable sensors capable of monitoring human movements with potential applications in personal health monitoring. These wearable devices could ultimately improve health care substantially while reducing its costs.Read moreRead less
Nanoporous siloxane membranes for ultrasound mediated ophthalmic drug delivery. This project will develop tailored polymers for use in a novel non-invasive ocular drug delivery device which treats vision threatening conditions such as age-related macular degeneration (AMD). The outcomes of this project will enable an entirely new ocular drug delivery technology, thereby delivering significant benefit to ophthalmic healthcare.
Directional fluid-transfer in thin porous materials with gradient wettability through thickness. This project will further strengthen Australia's world leading position in advanced fibrous materials research. It will provide a new platform technology to develop self-driven unidirectional fluid-transfer fabrics and porous membranes for diverse applications in daily life, healthcare, defence and a number of industrial processes.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100141
Funder
Australian Research Council
Funding Amount
$1,294,000.00
Summary
Facility for in-situ nuclear magnetic resonance of advanced materials and devices. This unique characterisation facility will support and enhance high-quality research in four key areas: electro-materials and nanotechnology, light metal alloys, biotechnology and energy related devices. This research will lead to new materials and new technologies in clean energy, carbon dioxide capture and health care.
Scalable and Applicable Nanostructured Adsorbents for Arsenic Removal with High Performance. Arsenic contamination in groundwater and drinking water affects over 100 million people worldwide and causes severe health problems. This project aims to use a recently patented technology to develop a new generation of adsorbents with controlled nanostructure and morphology for arsenic removal. The novel low-cost adsorbents are expected to have superior performance for the treatment of water containing ....Scalable and Applicable Nanostructured Adsorbents for Arsenic Removal with High Performance. Arsenic contamination in groundwater and drinking water affects over 100 million people worldwide and causes severe health problems. This project aims to use a recently patented technology to develop a new generation of adsorbents with controlled nanostructure and morphology for arsenic removal. The novel low-cost adsorbents are expected to have superior performance for the treatment of water containing arsenic at both high and low concentrations. The engineered products will be tested in high-throughput wastewater treatment in pharmaceutical factories and as a household drinking water treatment device. This project aims to bring economic and social benefits to Australian industry and improve the quality of life for people all over the world.Read moreRead less
Special Research Initiatives - Grant ID: SR180200051
Funder
Australian Research Council
Funding Amount
$497,638.00
Summary
Integrated platform technologies for remediation of PFAS contaminated water. This project aims to develop low cost platform technologies using our patented high capacity adsorbent material for the removal of perfluoralkyl substances (PFAS) from contaminated water sources in Australia. Our advanced adsorbent material is made from a novel sulfur co-polymer and activated carbon, both of which have high affinity for PFAS, but when combined as a composite provide significant advantages for PFAS remed ....Integrated platform technologies for remediation of PFAS contaminated water. This project aims to develop low cost platform technologies using our patented high capacity adsorbent material for the removal of perfluoralkyl substances (PFAS) from contaminated water sources in Australia. Our advanced adsorbent material is made from a novel sulfur co-polymer and activated carbon, both of which have high affinity for PFAS, but when combined as a composite provide significant advantages for PFAS remediation. This adsorbent will be applied in mobile water treatment plants for remediation of PFAS contaminated aquifers. We will also develop point-of-use water filters for individual, domestic use from the adsorbent, thus empowering individuals and local communities by delivering tangible solutions to Australia’s PFAS crisis.Read moreRead less