Gas-enriched slippery surfaces. This project will exploit novel experimental and simulations approaches to investigate gas enrichment at liquid-liquid interfaces, and its effect on interfacial slip. The outcomes of the project will be a deeper understanding of oil-water interfaces capturing the presence of interfacial gas layers, slippery surfaces with superior drag reducing and fouling reducing properties, and control over nanobubble formation under flow. The new surfaces will have potential ap ....Gas-enriched slippery surfaces. This project will exploit novel experimental and simulations approaches to investigate gas enrichment at liquid-liquid interfaces, and its effect on interfacial slip. The outcomes of the project will be a deeper understanding of oil-water interfaces capturing the presence of interfacial gas layers, slippery surfaces with superior drag reducing and fouling reducing properties, and control over nanobubble formation under flow. The new surfaces will have potential application in improving the energy efficiency of microfluidic and multiphase flow. Benefits are expected in terms of reduced emissions, fuel cost and pollution related to transport of goods by sea, and extraction of oil from rocks.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101788
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Shape sorting of nanoparticles at oil-water interfaces in microchannels. This project aims to study the effect of shape on the adsorption of nanoparticles at an oil/water interface and develop a rapid, inexpensive, efficient, versatile method for shape sorting of nanoparticles using a microfluidic approach. This technique can be applied for fractionation of synthetic nanoparticles, biosample analysis and environmental monitoring.
Lab-on-a-chip mass spectrometry tools for testing illicit drugs. This project aims to develop fit-for-purpose mass spectrometry tools for roadside and workplace testing of illicit drugs. The technology will be based on nanostructured semiconductor chips that are surface-functionalised to enable molecular capture without extensive sample processing and subsequent detection by a novel combination of techniques. The technology is expected to be applicable to saliva, sweat and urine samples.
Magnetic liquid marbles: a new droplet manipulation technique for channel-free microfluidics. The project will explore the feasibility of developing a new droplet-manipulation strategy by using magnetically responsive liquid marbles capable of hosting various liquid droplets. It will significantly advance the development of a new generation of microfluidic devices: magnetic field-actuated channel-free droplet microfluidics.
Biomimetic surface coatings for drag and fouling reduction. This project aims to provide new insights into liquid flow and adsorption at liquid/solid and liquid/liquid interfaces, by using a combination of theoretical predictions, nanoscale techniques and nanofabrication approaches. Expected outcomes are the development of liquid-repellent slippery surface coatings that reduce hydrodynamic drag and inhibit marine fouling. This will benefit the fields of advanced manufacturing and smart coatings, ....Biomimetic surface coatings for drag and fouling reduction. This project aims to provide new insights into liquid flow and adsorption at liquid/solid and liquid/liquid interfaces, by using a combination of theoretical predictions, nanoscale techniques and nanofabrication approaches. Expected outcomes are the development of liquid-repellent slippery surface coatings that reduce hydrodynamic drag and inhibit marine fouling. This will benefit the fields of advanced manufacturing and smart coatings, and will underpin a wide range of energy efficient processes and products. Slippery coatings will solve urgent environmental problems of social value by improving the energy and chemical efficiency in fluid flow, heat transfer, secondary oil recovery, microfluidics, and anti-fouling.Read moreRead less
Smart hybrid nano-biomaterials that mimic the pharmaceutical food effect. Smart biomaterials will be developed which when taken orally will act in our gut to improve drug and vitamin uptake. The breakthrough science will drive new pharmaceuticals and nutraceuticals for the future health of Australia, and economic benefits will result through increased exposure to the global market for delivering biomolecules.
Discovery Early Career Researcher Award - Grant ID: DE160100888
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Illuminating drug activity in the brain with nanocrystalline beacons. The project focuses on developing technologies to understand the activity of drugs and precisely locate their target sites in the brain. Novel nanocrystalline beacons and ultrahigh-sensitivity optical imaging technology developed in the project have the aim to help visualise opioid and other related drug molecules over extended periods, which is impossible with current methods. Quantifying drug target distribution in the brain ....Illuminating drug activity in the brain with nanocrystalline beacons. The project focuses on developing technologies to understand the activity of drugs and precisely locate their target sites in the brain. Novel nanocrystalline beacons and ultrahigh-sensitivity optical imaging technology developed in the project have the aim to help visualise opioid and other related drug molecules over extended periods, which is impossible with current methods. Quantifying drug target distribution in the brain and imaging their dynamics on a single molecule level will shed light on drug-target interactions.Read moreRead less
Tuning the electrolytes for high efficiency solar splitting of water. This project will develop a new technology that uses ionic liquids and sunlight to split water into hydrogen and oxygen to be used as a clean fuel. Australia has abundant sunlight, is very close to the growing energy markets of the Asia-Pacific region, and is ideally placed to benefit from this new technology.
Discovery Early Career Researcher Award - Grant ID: DE120100042
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Study of oriented attachment of nanocrystals at oil-water interfaces. This project will study the fundamental issues for crystal growth, which will dramatically facilitate the development of effective pathways for the synthesis of advanced nanomaterials for nanodevice and nanotechnology. The obtained outcomes will enhance our knowledge in crystal growth and colloid sciences.
Harnessing lipid nano-assembly for next generation functional foods and pharmaceutical products. Nature assembles lipid molecules from our diet into useful structures in our gastrointestinal tract with remarkable precision and versatility. By understanding and harnessing these processes we can design new lipid-based nanomaterials leading to more effective functional foods and pharmaceutical products with reduced side effects.