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.
Discovery Early Career Researcher Award - Grant ID: DE160101101
Funder
Australian Research Council
Funding Amount
$348,741.00
Summary
Single-Molecule Circuitry for Nanoscale Electronic Devices. The aim of this project is to develop novel methods for forming robust single-molecule circuitry. The use of single molecules in electronics represents the next level of miniaturisation of electronic components, which would enable us to meet the expanding demands of modern technologies and to continue the downscaling trend in electronic devices. This project aims to address the requirements needed to translate single-molecule electronic ....Single-Molecule Circuitry for Nanoscale Electronic Devices. The aim of this project is to develop novel methods for forming robust single-molecule circuitry. The use of single molecules in electronics represents the next level of miniaturisation of electronic components, which would enable us to meet the expanding demands of modern technologies and to continue the downscaling trend in electronic devices. This project aims to address the requirements needed to translate single-molecule electronics from its current status as a fundamental tool to real-world applications. Key approaches will be the use of surface chemistry to develop new methods of wiring single molecules and the integration of robust single-molecule junctions with semiconducting electrodes. The expected project outcomes pave the way for single-molecule electronic and analytical devices.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100589
Funder
Australian Research Council
Funding Amount
$402,711.00
Summary
Cadmium-free one-dimensional colloidal nanocrystal heterostructures. The goal of this project is to develop innovative colloidal nanocrystal heterostructures to provide the basis for eco-friendly optoelectronic devices and photocatalysis as well as other advanced applications. One-dimensional semiconductor nanocrystals have desirable electronic and catalytic properties (a linearly polarised emission, large absorption cross section, reduced lasing threshold and improved charge separation and tran ....Cadmium-free one-dimensional colloidal nanocrystal heterostructures. The goal of this project is to develop innovative colloidal nanocrystal heterostructures to provide the basis for eco-friendly optoelectronic devices and photocatalysis as well as other advanced applications. One-dimensional semiconductor nanocrystals have desirable electronic and catalytic properties (a linearly polarised emission, large absorption cross section, reduced lasing threshold and improved charge separation and transport). However, present investigations of these materials are mainly limited to highly toxic cadmium chalcogenides. This project aims to explore a family of cadmium-free colloidal nanocrystal heterostructures with the desired properties. The project intends to investigate their growth mechanisms, properties and effects to support product development and advance the fundamental knowledge of electronics at the nanoscale.Read moreRead less
Engineering nanosheet-based novel structures. Microscopic structures will be engineered based on super thin materials, which promise to deliver significant advancements in the development of high sensitivity detectors, and efficient energy conversion and storage devices. This project will develop techniques that are not only green but also possess the flexibility to tailor-make novel structures.
Discovery Early Career Researcher Award - Grant ID: DE150100118
Funder
Australian Research Council
Funding Amount
$301,751.00
Summary
Controlling Defects in 2D Materials for Advanced Optoelectronics. Control over defect densities in 2D transition metal chalcogenide films permit controlled fabrication of van der Waals heterostructures and other ultra-thin electronic devices. This is crucial for controlling the optoelectronic properties of devices, yet, unlike bulk semiconductors, defect and dopant control in 2D transition metal chalcogenides is not presently possible. This project aims to investigate the optical properties of s ....Controlling Defects in 2D Materials for Advanced Optoelectronics. Control over defect densities in 2D transition metal chalcogenide films permit controlled fabrication of van der Waals heterostructures and other ultra-thin electronic devices. This is crucial for controlling the optoelectronic properties of devices, yet, unlike bulk semiconductors, defect and dopant control in 2D transition metal chalcogenides is not presently possible. This project aims to investigate the optical properties of single-defects, and how to control them using sensitive microscopy and controlled ligand deposition. Simultaneous electronic characterisation and single-defect microscopy in fabricated thin-film transistors will be investigated to correlate optical and electronic properties of thin-film devices.Read moreRead less
Remediation of groundwater using permeable reactive barriers. Permeable reactive barriers are passive subsurface installations that remove contamination from groundwater as it flows through a reactive substrate. This project will develop new permeable reactive barriers that will benefit the nation by building skills and knowledge in an area of growth in Australian industry, namely the rehabilitation of industrial lands and the protection and remediation of Australia's critical groundwater source ....Remediation of groundwater using permeable reactive barriers. Permeable reactive barriers are passive subsurface installations that remove contamination from groundwater as it flows through a reactive substrate. This project will develop new permeable reactive barriers that will benefit the nation by building skills and knowledge in an area of growth in Australian industry, namely the rehabilitation of industrial lands and the protection and remediation of Australia's critical groundwater sources. The project is aimed at remediating an industrially contaminated site in the Hunter Valley, New South Wales, thereby contributing to the environmental improvement of that region. The technology developed will have wide application to other sites, both nationally and internationally.Read moreRead less
Closing the data gap: High throughput screening of nanoparticle toxicity. The nanotechnology sector is experiencing an exponential growth period with over 100 products containing manufactured nanoparticles entering the market every year. Ensuring growth of the sector needs to be balanced against the imperative of protecting both human and environmental safety. This project aims to develop new methodological and conceptual avenues to close the gap between innovation in nanotechnology and risk ass ....Closing the data gap: High throughput screening of nanoparticle toxicity. The nanotechnology sector is experiencing an exponential growth period with over 100 products containing manufactured nanoparticles entering the market every year. Ensuring growth of the sector needs to be balanced against the imperative of protecting both human and environmental safety. This project aims to develop new methodological and conceptual avenues to close the gap between innovation in nanotechnology and risk assessment. This is intended to be achieved by developing and validating high-throughput in vitro toxicity screening platforms for manufactured nanoparticles. The approach is based on advanced lab-on-a-chip microfluidic technologies. The predictive power of the platform will be refined and optimised via ex-vivo and in-vivo models.Read moreRead less
Geometry variation and coupling of single gold nanorods for highly efficient, one-photon and two-photon luminescent markers. The search for highly efficient, non toxic and stable luminescence markers is continuing for many applications in bio- and nano-photonics. The project's study of gold nanorod luminescence is designed to fundamentally understand and control the luminescence quantum efficiency of gold nanorod and ultimately unveil its potential as the future marker.
Discovery Early Career Researcher Award - Grant ID: DE150100427
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
All-in-one Functional Nanocrystal Inks for Printed Inorganic Solar Cells. At present, manufacturing solar panels involves expensive high temperature and high vacuum processes. The bottleneck to cheaper solar power is the ability to design new methods of manufacturing. The ability to print the active components of a solar cell is an excellent way to mitigate these costs. This project aims to focus on developing the knowledge to print the most crucial component of a solar cell - the light absorbin ....All-in-one Functional Nanocrystal Inks for Printed Inorganic Solar Cells. At present, manufacturing solar panels involves expensive high temperature and high vacuum processes. The bottleneck to cheaper solar power is the ability to design new methods of manufacturing. The ability to print the active components of a solar cell is an excellent way to mitigate these costs. This project aims to focus on developing the knowledge to print the most crucial component of a solar cell - the light absorbing layer. Innovative nanoscience will be used to develop novel solar inks composed of tiny semiconductor crystals. The formulation and transformation of these inks into efficient semiconductor light absorbing layers, with a clear view to cheaper printed solar cells, will be the key objective of this project.Read moreRead less
Theoretical foundations of dynamic surface forces. Australian scientists are current world leaders in developing novel materials for biomedical and industrial applications. This project will create the key theoretical framework to interpret experimental measurements and will be vital in ensuring that our scientific endeavour in novel materials maintains its current world leadership position.