Discovery Early Career Researcher Award - Grant ID: DE160100715
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
Tunable plasmonics in ultra-doped transition metal oxides and chalcogenides. The project is designed to explore new classes of plasmonic materials based on low-dimensional transition metal oxide and chalcogenide nanostructures. These crystals, with stratified structures and high surface affinities to charged particles, present a new frontier in plasmonics by allowing reversible stimuli induced doping and defect embedding. The project plans to focus on achieving tunable plasmonic properties acros ....Tunable plasmonics in ultra-doped transition metal oxides and chalcogenides. The project is designed to explore new classes of plasmonic materials based on low-dimensional transition metal oxide and chalcogenide nanostructures. These crystals, with stratified structures and high surface affinities to charged particles, present a new frontier in plasmonics by allowing reversible stimuli induced doping and defect embedding. The project plans to focus on achieving tunable plasmonic properties across a broad spectrum from ultraviolet to infrared light. Targets are systems with low propagation losses or ultra-sensitivity towards environmental changes. The anticipated outcomes will serve as a base to establish the next generation plasmonic communication and sensing systems with active on-chip controllability, which could be used as the base of future telecommunications, energy harvesting and sensing systems.Read moreRead less
Conducting polymer materials. This project aims to understand the optical, electrical and optoelectronic properties of conductive polymers by studying how ions influence the charge transport through the polymeric structure. The discovery of conductive polymers in the 1970s led to smartphone and laptop touch displays and solar cells. These materials promise even more still – but how they operate at the atomic level is not understood. This project could lead to an ability to harness and control th ....Conducting polymer materials. This project aims to understand the optical, electrical and optoelectronic properties of conductive polymers by studying how ions influence the charge transport through the polymeric structure. The discovery of conductive polymers in the 1970s led to smartphone and laptop touch displays and solar cells. These materials promise even more still – but how they operate at the atomic level is not understood. This project could lead to an ability to harness and control these properties for energy storage and wearable displays. These materials’ biological neutrality could lead to drug delivery and sensing applications in the agriculture and healthcare spaces.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100087
Funder
Australian Research Council
Funding Amount
$1,100,000.00
Summary
Plasma-focused ion beam for nanoscale characterisation of materials. This project aims to enable research programmes in functional materials to characterise materials using xenon-plasma focused ion beam (FIB) instrumentation. The plasma FIB, with its fast milling speeds across large areas, will enable new three-dimensional imaging experiments and types of transmission electron microscopy samples. This will have applications in engineering, photovoltaics and environmental geosciences, which all n ....Plasma-focused ion beam for nanoscale characterisation of materials. This project aims to enable research programmes in functional materials to characterise materials using xenon-plasma focused ion beam (FIB) instrumentation. The plasma FIB, with its fast milling speeds across large areas, will enable new three-dimensional imaging experiments and types of transmission electron microscopy samples. This will have applications in engineering, photovoltaics and environmental geosciences, which all need to analyse materials on a nanometre scale.Read moreRead less
Novel graphene-based soft materials for versatile applications. This research program will develop new techniques to convert natural graphite into new carbon nanomaterials for use in energy storage/conversion devices, water purification, sensors and biomedical devices. It will enable many technological innovations in related areas and enhance Australia's engineering and manufacturing innovations.
Platform technologies for multifunctional nanocarrier systems. Smart targeted nanocarriers offer new opportunities for drug delivery. This project aims to develop new platforms for reproducibly producing and screening targeted nanocarriers. The platform technologies developed in this project aim to revolutionise current strategies for designing and evaluating drug delivery systems, and will accelerate the clinical translation of targeted drug delivery. This will include a novel one-step microflu ....Platform technologies for multifunctional nanocarrier systems. Smart targeted nanocarriers offer new opportunities for drug delivery. This project aims to develop new platforms for reproducibly producing and screening targeted nanocarriers. The platform technologies developed in this project aim to revolutionise current strategies for designing and evaluating drug delivery systems, and will accelerate the clinical translation of targeted drug delivery. This will include a novel one-step microfluidic platform technology for reproducibly producing targeted polymer nanocarriers having systematically varied properties, a dual-templating method for making targeted silica nanocapsules and new design of in vivo-mimicking 'Tissue Chips' for screening and evaluating the nanocarriers.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100051
Funder
Australian Research Council
Funding Amount
$320,000.00
Summary
An advanced X-ray facility for surface and in-situ materials characterization. An advanced X-ray facility for surface and in-situ materials characterisation: Materials properties are crucial to the performance of devices and structures, and detailed characterisation at a molecular level is important for optimizing new materials. X-rays are a powerful means of achieving the required level of detail in structural characterisation. The aim of this project is to make available an extremely bright X- ....An advanced X-ray facility for surface and in-situ materials characterization. An advanced X-ray facility for surface and in-situ materials characterisation: Materials properties are crucial to the performance of devices and structures, and detailed characterisation at a molecular level is important for optimizing new materials. X-rays are a powerful means of achieving the required level of detail in structural characterisation. The aim of this project is to make available an extremely bright X-ray source with a suite of advanced analytical tools, including surface structural analysis by reflectometry and grazing incidence diffraction and materials structure determination using powder diffraction and microdiffraction at high and low temperatures. The functions of this facility are broad and its applications include materials science, organic electronics, biomaterials and engineering.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100040
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
Advanced capabilities for surface engineering and nanolithography . Advanced capabilities for surface engineering and nanolithography: This project will establish a facility for atomic layer deposition and nanolithography. Strong fabrication and engineering capabilities are key in keeping interdisciplinary research highly competitive. The applications of these cutting-edge surface nanoengineering technologies are enormous and include: development of new materials with new properties for sensing, ....Advanced capabilities for surface engineering and nanolithography . Advanced capabilities for surface engineering and nanolithography: This project will establish a facility for atomic layer deposition and nanolithography. Strong fabrication and engineering capabilities are key in keeping interdisciplinary research highly competitive. The applications of these cutting-edge surface nanoengineering technologies are enormous and include: development of new materials with new properties for sensing, biosensing, optical, photonic, electronic and medical devices, new metamaterials, solar cell, energy production and environmental protection.Read moreRead less
Enhance ferromagnetic ordering by exchange coupling and defect engineering. This project aims to achieve room temperature ferromagnetism in two-dimensional materials via magnetic element doping and defect and interface engineering. Achieving high spin polarisation, high spin diffusion length and effective spin manipulation, the pre-requisites for functional spintronics devices, makes research into two-dimensional materials for spintronics applications difficult. This project could establish a so ....Enhance ferromagnetic ordering by exchange coupling and defect engineering. This project aims to achieve room temperature ferromagnetism in two-dimensional materials via magnetic element doping and defect and interface engineering. Achieving high spin polarisation, high spin diffusion length and effective spin manipulation, the pre-requisites for functional spintronics devices, makes research into two-dimensional materials for spintronics applications difficult. This project could establish a solid foundation for realising qualified spintronics materials for spintronics devices. The expected outcomes are low power, high speed, spintronics devices, enhancing Australia’s strength in spintronics research.Read moreRead less
The development of advanced diluted magnetic semiconductors through nonmagnetic element doping and defect engineering for spin transistors. This project is to develop advanced diluted magnetic semiconductor materials by nonmagnetic element doping and defects engineering for the fabrication of spin devices (for example, spin transistors) and to understand the physics and engineering science of 'spin' behaviour.
New stimuli-responsive polymer membranes using graphene as a multifunctional scaffold. Membranes are used in a range of applications to filter liquids and gases and increasingly must be able to be activated by stimuli such as temperature, pH and voltage. We will develop a new type of membrane which is easy to make, is strong and allows the incorporation of a variety of stimuli-responsive polymers within a functional graphene scaffold.