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.
Development of high performance III-V semiconductor photoconductive antennas for terahertz applications. The practical applications of terahertz (THz) radiation include scientific probing for material characterisation, screening for weapons, explosives and biohazards, imaging for concealed objects and medical diagnostics, chemical and biological analysis, astronomy and space research. The success of this project will lead to the creation of a new generation of high performance THz emitters/detec ....Development of high performance III-V semiconductor photoconductive antennas for terahertz applications. The practical applications of terahertz (THz) radiation include scientific probing for material characterisation, screening for weapons, explosives and biohazards, imaging for concealed objects and medical diagnostics, chemical and biological analysis, astronomy and space research. The success of this project will lead to the creation of a new generation of high performance THz emitters/detectors essential for above applications, making great contribution to the Nation in the areas of science, technology, health, security and economy.Read moreRead less
A high performance and environment-friendly piezoelectric detector platform for biosensor applications. The development of high performance, lead-free, piezoelectric films and their incorporation into devices is rapidly becoming an urgent task as a result of recent legislation banning the use of lead in electronic components. The successful development of piezoelectric biosensors, as proposed in this project, has numerous potential benefits including the prospect of rapid and cheap biosensor dev ....A high performance and environment-friendly piezoelectric detector platform for biosensor applications. The development of high performance, lead-free, piezoelectric films and their incorporation into devices is rapidly becoming an urgent task as a result of recent legislation banning the use of lead in electronic components. The successful development of piezoelectric biosensors, as proposed in this project, has numerous potential benefits including the prospect of rapid and cheap biosensor devices as well as an environment-friendly, sensitive and real time solution for on-site drug, chemical and biological sensing. Successful development of the latter would provide immediate benefit in the areas of national security, food safety as well as in environmental and health monitoring. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101359
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Hierarchical 3D metal organic frameworks for the microfabrication of advanced biomedical devices. This project will produce three-dimensional porous structures for use in sensing devices and biomedical implants. Metal-organic frameworks (MOFs) are versatile ultra high surface area materials with controllable pore size, chemical properties and functionalisation. These new materials will be incorporated into portable biosensing devices which are highly sensitive and reliable. The project involves ....Hierarchical 3D metal organic frameworks for the microfabrication of advanced biomedical devices. This project will produce three-dimensional porous structures for use in sensing devices and biomedical implants. Metal-organic frameworks (MOFs) are versatile ultra high surface area materials with controllable pore size, chemical properties and functionalisation. These new materials will be incorporated into portable biosensing devices which are highly sensitive and reliable. The project involves three streams including preparation of the three-dimensional metal scaffolds utilizing state-of-the-art direct manufacturing technologies; integration of MOFs on the three-dimensional metal scaffolds using the metallic structure as the source of the MOF metal ions; and incorporation of bio-active molecules into the three-dimensional hierarchically porous structure for the purpose of bio-device fabrication.Read moreRead less
Ferroelectric piezoelectric materials and key problems associated with their applications in mechanical, electrical and optical energy transformations. This project aims to investigate the dynamic microstructure of ferroelectric piezoelectric materials in response to electrical fields or mechanical stresses, and therefore identify the factors enhancing the mechanical, electrical and optical couplings for intentional improvement and development of these materials for use in energy transformations ....Ferroelectric piezoelectric materials and key problems associated with their applications in mechanical, electrical and optical energy transformations. This project aims to investigate the dynamic microstructure of ferroelectric piezoelectric materials in response to electrical fields or mechanical stresses, and therefore identify the factors enhancing the mechanical, electrical and optical couplings for intentional improvement and development of these materials for use in energy transformations.Read moreRead less
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.
Carbon nanotube fluidic channels for desalination - interplay of nanoscale confinement and electrostatics. Tiny tubes of carbon, ten thousand times smaller than human hair, allow water to pass through at extraordinary speed. This project aims to understand and improve their salt rejection properties using comprehensive experimental and theoretical approaches. This will provide the impetus and knowledge for developing advanced membranes for desalination
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453732
Funder
Australian Research Council
Funding Amount
$726,164.00
Summary
Interactive network for plasma and surface analysis. Plasma-based materials synthesis and surface modification methods have great value because they allow a wide range of ion energies and processing conditions to be achieved. Accurate in-situ measurement of the plasma conditions is crucial to the development of reliable new processes. This proposal will establish unique capabilities for carrying out diagnostic studies of plasma surface treatment technologies. The proposal will link Australia's m ....Interactive network for plasma and surface analysis. Plasma-based materials synthesis and surface modification methods have great value because they allow a wide range of ion energies and processing conditions to be achieved. Accurate in-situ measurement of the plasma conditions is crucial to the development of reliable new processes. This proposal will establish unique capabilities for carrying out diagnostic studies of plasma surface treatment technologies. The proposal will link Australia's most advanced plasma processing and diagnostic equipment located at the University of Sydney and the ANU to advanced materials and surface analysis facilities at La Trobe and RMIT Universities in Melbourne, using interactive e-science links and vacuum sample-transfer facilities.Read moreRead less
Transistor-based sensor technology for fast, reliable and accurate in situ monitoring of recycled wastewater. Water recycling is becoming critical for water supplies worldwide, due to declining natural supplies of fresh water, combined with increasing demand. The greatest community and industry concerns over recycled water are quality assurance and relative cost. Ensuring quality requires monitoring of contaminants, yet no single real-time technology exists to measure the myriad of potential con ....Transistor-based sensor technology for fast, reliable and accurate in situ monitoring of recycled wastewater. Water recycling is becoming critical for water supplies worldwide, due to declining natural supplies of fresh water, combined with increasing demand. The greatest community and industry concerns over recycled water are quality assurance and relative cost. Ensuring quality requires monitoring of contaminants, yet no single real-time technology exists to measure the myriad of potential contaminants. This project will develop technology using AlGaN/GaN-based transistors, sensitised to different contaminants, enabling multi-analyte real-time sensor arrays. In situ monitoring systems based on such arrays will be fast, accurate, reliable, low-cost, and applicable to a broad variety of water recycling projects.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100569
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Ultra-Porous Devices by Synergistic Aerosol and Atomic Layer Depositions. The project aspires to develop a scalable low-cost approach for the synthesis and integration of ultra-porous films in nanodevices. The project intends to deposit atomic layers onto aerogel-like nanoparticle networks, self-assembled by thermophoresis of flame-made aerosols. This would increase the atomically-deposited layer mass by several hundred-fold per cycle and result in ultra-porous films with electrochemically activ ....Ultra-Porous Devices by Synergistic Aerosol and Atomic Layer Depositions. The project aspires to develop a scalable low-cost approach for the synthesis and integration of ultra-porous films in nanodevices. The project intends to deposit atomic layers onto aerogel-like nanoparticle networks, self-assembled by thermophoresis of flame-made aerosols. This would increase the atomically-deposited layer mass by several hundred-fold per cycle and result in ultra-porous films with electrochemically active surface areas. It is intended that the project will demonstrate the fabrication of solid–gas, solid–liquid and solid–solid nanointerfaces, which will be applicable to key emerging technologies such as wearable medical diagnostics.Read moreRead less