Near Infrared (IR) Laser Dyes for Latent Fingermark Detection. This project will enable Australian law enforcement agencies to recover latent fingerprints from difficult surfaces through the use of near infrared dyes. The project will allow the recovery of fingerprints from a scene which would otherwise be lost to an investigation. We will provide new fingerprint development techniques and imaging methods to law enforcement agencies, enhancing their ability to identify a perpetrator and thereb ....Near Infrared (IR) Laser Dyes for Latent Fingermark Detection. This project will enable Australian law enforcement agencies to recover latent fingerprints from difficult surfaces through the use of near infrared dyes. The project will allow the recovery of fingerprints from a scene which would otherwise be lost to an investigation. We will provide new fingerprint development techniques and imaging methods to law enforcement agencies, enhancing their ability to identify a perpetrator and thereby reducing crime rates.Read moreRead less
Nanoparticle adsorption at air-water interfaces for foam stabilization. Pharmaceutical formulations and lightweight materials and processes such as mineral flotation and biocatalysis depend on the interactions between air bubbles and particles in water. This project will provide in-depth insight into how the physics and chemistry of the particle surfaces control the structure of the materials formed in those processes.
Discovery Early Career Researcher Award - Grant ID: DE140100549
Funder
Australian Research Council
Funding Amount
$373,220.00
Summary
Stratiform Optical Barcoding System for Cardiac Biomarkers: Towards Smart Computerised Clinical Prognosis of Cardiovascular Disease. This project involves the development of an innovative optical biosensing system combined with a sophisticated barcode system containing information for clinical diagnosis of cardiovascular disease. For the first time, this system will provide information on the amount and chemical structure of cardiac biomarkers at the same time by combining reflectometric interfe ....Stratiform Optical Barcoding System for Cardiac Biomarkers: Towards Smart Computerised Clinical Prognosis of Cardiovascular Disease. This project involves the development of an innovative optical biosensing system combined with a sophisticated barcode system containing information for clinical diagnosis of cardiovascular disease. For the first time, this system will provide information on the amount and chemical structure of cardiac biomarkers at the same time by combining reflectometric interference and low resolution Raman spectroscopies. These optical signals will be converted into barcodes containing several levels of information, which will be at the base of this versatile point-of-care test. The obtained results will be implemented in a computerised database to improve current cardiac disease diagnosis.Read moreRead less
A nanoengineered solution to drug delivery in bone. This project presents an exciting new approach of applying nanotechnology to bone research. By combining our expertise in nanoengineering of new materials, mathematical modelling and bone biology, this project will result in a well-characterised model for drug delivery into bone and lead to a new therapeutic approach for treating bone diseases.
The Nanotechnology Desalination Research Project - Low Energy Desalination Membranes. Population growth and global warming is rapidly increasing the strain placed on fresh water supplies. Environmentally sustainable solutions to this water shortage need to be found urgently. This project will develop new, low energy desalination technologies which can be powered by renewable energy sources, to enable desalination to be widely applied with low environmental impacts. It addresses several national ....The Nanotechnology Desalination Research Project - Low Energy Desalination Membranes. Population growth and global warming is rapidly increasing the strain placed on fresh water supplies. Environmentally sustainable solutions to this water shortage need to be found urgently. This project will develop new, low energy desalination technologies which can be powered by renewable energy sources, to enable desalination to be widely applied with low environmental impacts. It addresses several national priorities: Water - a critical resource; Transforming existing industries; Overcoming soil loss, salinity and acidity; Responding to climate change and variability; Frontier technologies and Advanced materials.Read moreRead less
Next generation easy-clean lenses by robust liquid-repellent nanotextures. This project aims to produce better performing self-cleaning lenses, which are less likely to get dirty and are easy to clean. It will develop water and oil repellent coatings with superior optical transparency and mechanical, solvent and UV stability for both hard coated and anti-reflection coated optical lenses. Engineering of stable, ultra-liquid repellent nanomaterials on transparent surfaces will create a foundation ....Next generation easy-clean lenses by robust liquid-repellent nanotextures. This project aims to produce better performing self-cleaning lenses, which are less likely to get dirty and are easy to clean. It will develop water and oil repellent coatings with superior optical transparency and mechanical, solvent and UV stability for both hard coated and anti-reflection coated optical lenses. Engineering of stable, ultra-liquid repellent nanomaterials on transparent surfaces will create a foundation of knowledge for the industrial development of the future generation of easy care coatings, with vast application potential.Read moreRead less
Patchy colloidosomes at interfaces: correlation of particle surface heterogeneity, wettability, and chemical activity at the nanoscale. The surfaces of natural mineral particles are made up of spots with such different chemical and physical properties. The complexity makes it hard to predict their behaviour. This project will provide insights into how the 'patchy' nature of particle surfaces affects their behaviour in processes such as flotation separation and bio-fuel production.
New nanocomposites of porous materials and visible light sensitive TiO2 for efficient wastewater purification. The innovative newly proposed materials can trap and efficiently decompose dissolved organics in the same process, without generating any waste for disposal. No UV is required and the solar radiation can be efficiently used. The proposed research will be a significant breakthrough in the field of water treatment that reduces energy consumption, uses low cost materials and provides a rea ....New nanocomposites of porous materials and visible light sensitive TiO2 for efficient wastewater purification. The innovative newly proposed materials can trap and efficiently decompose dissolved organics in the same process, without generating any waste for disposal. No UV is required and the solar radiation can be efficiently used. The proposed research will be a significant breakthrough in the field of water treatment that reduces energy consumption, uses low cost materials and provides a real solution. The research findings will be useful to a wide spectrum of manufacturing industries which are currently generating slightly contaminated wastewater, and will be beneficial to the community in general. At the same time, the industries will be a step forward toward sustainable manufacturing.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100146
Funder
Australian Research Council
Funding Amount
$800,000.00
Summary
Ultra high vacuum scanning probe microscope facility. Ultra high-vacuum scanning tunneling microscopy underpins advances in the understanding of novel materials for electronics, engineering and medical applications, including thin-films, nanostructures, advanced semiconductors, nanostructured (organic or inorganic) conductors, and nanoscale interfaces (heteronanostructures). It is a core technique underpinning the new Superscience agenda in Future Technologies. A number of present and future re ....Ultra high vacuum scanning probe microscope facility. Ultra high-vacuum scanning tunneling microscopy underpins advances in the understanding of novel materials for electronics, engineering and medical applications, including thin-films, nanostructures, advanced semiconductors, nanostructured (organic or inorganic) conductors, and nanoscale interfaces (heteronanostructures). It is a core technique underpinning the new Superscience agenda in Future Technologies. A number of present and future research fields will benefit from the presence of this instrument, which will enhance Australia's competitiveness in nanotechnology research and development. Training of PhD and graduate students in this area is essential to exploit the potentiality of nanotechnology for the future benefit of Australia.Read moreRead less