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
Tailoring metal-organic framework catalysts for carbon dioxide conversion. Reducing the greenhouse gas, CO2, into valuable fuels would be beneficial for relieving energy shortage and improving global sustainability. This project aims to synthesise high-performance heterogeneous catalysts for CO2 conversion by periodic ordering photo-redox metalloligand and thermal-catalytically active metal oxide clusters in metal-organic frameworks (MOFs). This approach is expected to deliver a unique single-si ....Tailoring metal-organic framework catalysts for carbon dioxide conversion. Reducing the greenhouse gas, CO2, into valuable fuels would be beneficial for relieving energy shortage and improving global sustainability. This project aims to synthesise high-performance heterogeneous catalysts for CO2 conversion by periodic ordering photo-redox metalloligand and thermal-catalytically active metal oxide clusters in metal-organic frameworks (MOFs). This approach is expected to deliver a unique single-site metal-organic framework catalyst with high reaction-activity and chemo-selectivity in converting CO2 into valuable chemicals. This advancement will provide significant benefits for Australia’s emerging chemical manufacturing industry, and ultimately leading to a carbon-neutral energy economy and environment.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100100
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Liquid metal chemistry towards grain boundary-free electronic materials. This project aims to develop ultra-thin materials with minimal grain boundaries for electronic applications by advancing knowledge of liquid metal chemistry. The difficulty of synthesising high quality, low-dimensional materials, particularly atomically-thin films, is the major impediment prohibiting the wide scale use of semiconducting nanosheets by the electronics industries. Improving crystal quality, while also offering ....Liquid metal chemistry towards grain boundary-free electronic materials. This project aims to develop ultra-thin materials with minimal grain boundaries for electronic applications by advancing knowledge of liquid metal chemistry. The difficulty of synthesising high quality, low-dimensional materials, particularly atomically-thin films, is the major impediment prohibiting the wide scale use of semiconducting nanosheets by the electronics industries. Improving crystal quality, while also offering scalability, is a key challenge. This project will develop new synthetic approaches by using room temperature liquid metal based chemistry. The outcomes of this project will lay the foundation of the industrial scale application of these highly functional materials, which will enable cost efficient production of energy efficient electronics.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190101514
Funder
Australian Research Council
Funding Amount
$352,473.00
Summary
Nanodroplet platforms for engineering novel nanocarbon structures. This project aims to exploit surface nanodroplet array platforms to construct multi-scale level assembly of nanometer-scale carbon materials. The project expects to advance knowledge on the interactions between droplets and carbon nanomaterials to enable controlled construction of nanocarbon based optoelectric devices. Successful adoption of nanocarbon material-based optoelectronic devices by the energy conversion industry has th ....Nanodroplet platforms for engineering novel nanocarbon structures. This project aims to exploit surface nanodroplet array platforms to construct multi-scale level assembly of nanometer-scale carbon materials. The project expects to advance knowledge on the interactions between droplets and carbon nanomaterials to enable controlled construction of nanocarbon based optoelectric devices. Successful adoption of nanocarbon material-based optoelectronic devices by the energy conversion industry has the potential to increase efficiency of conversion and reduce the cost of manufacture. The expected outcomes are large scale and well-ordered nanocarbon structures with excellent electronic and optical properties.Read moreRead less
Understanding the role of catalysts in the epitaxial growth of multinary III-V semiconductor nanowires and nanowire heterostructures. This project will address a bottle-neck problem in the nanowire community. The outcomes of this project will provide new knowledge in nanoscience and guidelines for the development of nanowire-based nanodevices and nanosystems. This is strategically important to place Australia at the forefront of developments on nanoscience and nanotechnology.