Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100073
Funder
Australian Research Council
Funding Amount
$468,474.00
Summary
Nanoimprint systems: expanding research capability of roll to roll printer. This project aims to strengthen Australian research activities in the development of advanced multifunctional materials through the purchase of thermal and ultraviolet (UV) nano-imprint lithography modules to expand the nanofabrication capacity of roll-to-roll printer line. The various processes used to make nano-sized devices and components fall into two major categories, coating and patterning. Integrating the thermal ....Nanoimprint systems: expanding research capability of roll to roll printer. This project aims to strengthen Australian research activities in the development of advanced multifunctional materials through the purchase of thermal and ultraviolet (UV) nano-imprint lithography modules to expand the nanofabrication capacity of roll-to-roll printer line. The various processes used to make nano-sized devices and components fall into two major categories, coating and patterning. Integrating the thermal and UV nanoimprint lithography modules into the roll-to-roll printer line will provide a unique and simple materials fabrication platform. It will combine coating and nanolithography processes in a low cost, high-throughput and high-resolution format for advanced nanofabrication of microelectronic, telecommunication, biomedical and energy devices.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220101103
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
Giant piezo responses in rare-earth doped eco-friendly relaxor perovskites. This project aims to design and fabricate superior eco-friendly substitutions for lead-based perovskites widely used in piezoelectric devices, to address the long-standing toxic concern of lead for human beings and the environment in the community. It is expected to surmount the fundamental limit of current approaches to reach giant room-temperature piezoelectric responses in lead-free perovskites through using a pioneer ....Giant piezo responses in rare-earth doped eco-friendly relaxor perovskites. This project aims to design and fabricate superior eco-friendly substitutions for lead-based perovskites widely used in piezoelectric devices, to address the long-standing toxic concern of lead for human beings and the environment in the community. It is expected to surmount the fundamental limit of current approaches to reach giant room-temperature piezoelectric responses in lead-free perovskites through using a pioneering route named rare-earth doped relaxor/morphotropic phase boundary crossover. Success of this project will not only meet the Australia’s ecological sustainability goals, but also provide commercial opportunities for Australia in the large market of piezoelectric devices (> 25 Billion USD annually).Read moreRead less
High performance complex oxide heterostructures for nanoelectronic devices. This project aims to develop a material with ultrahigh electron mobility and conductivity well above today’s materials at room temperature to enable next generation nanoelectronics. The demand for higher performance and lower power consumption in electronic systems drives the creation of materials for devices in nanometre scale. The success of these materials depends on enhancement in carrier mobility and conductivity. T ....High performance complex oxide heterostructures for nanoelectronic devices. This project aims to develop a material with ultrahigh electron mobility and conductivity well above today’s materials at room temperature to enable next generation nanoelectronics. The demand for higher performance and lower power consumption in electronic systems drives the creation of materials for devices in nanometre scale. The success of these materials depends on enhancement in carrier mobility and conductivity. This project will spatially separate the electron generation layer from the conduction layer by individually engineering the atomically sharp complex oxide heterointerfaces to enhance the electron mobility and density. This is expected to develop new materials and nanoelectronic technologies.Read moreRead less
Engineered control of polarisation rotation in ferroelectric bilayers. This project aims to develop interface engineered nanoscale ferroelectric thin films with functional properties suitable for integration. Bulk ferroelectrics form the core of traditional stand-alone electromechanical devices such as sensors, actuators and ultrasonic devices. Future applications need to be integrated into thin film form on semiconductor wafers, but the attachment to the wafer induces a mechanical constraint, w ....Engineered control of polarisation rotation in ferroelectric bilayers. This project aims to develop interface engineered nanoscale ferroelectric thin films with functional properties suitable for integration. Bulk ferroelectrics form the core of traditional stand-alone electromechanical devices such as sensors, actuators and ultrasonic devices. Future applications need to be integrated into thin film form on semiconductor wafers, but the attachment to the wafer induces a mechanical constraint, which dramatically suppresses the electromechanical response. This project aims to solve this problem by "polarisation rotation", achieved by layered stacking of thin film ferroelectrics. Engineered control of ferroelectric polarization rotation could be the pathway to modern electromechanical devices.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.
Discovery Early Career Researcher Award - Grant ID: DE200101244
Funder
Australian Research Council
Funding Amount
$417,276.00
Summary
Advanced zinc-ion batteries with high voltage and high energy density. Zinc-ion battery is not only cheaper than current lithium-ion battery (LIB), but it is safer due to a neutral aqueous electrolyte. However, its grid-scale development is plagued by limited output voltage and inadequate energy density compared with more mainstream LIB. This project aims to solve the discharge-voltage problem by fabricating atomic-level structure engineered manganese (Mn)-based cathode and a new stable solid-st ....Advanced zinc-ion batteries with high voltage and high energy density. Zinc-ion battery is not only cheaper than current lithium-ion battery (LIB), but it is safer due to a neutral aqueous electrolyte. However, its grid-scale development is plagued by limited output voltage and inadequate energy density compared with more mainstream LIB. This project aims to solve the discharge-voltage problem by fabricating atomic-level structure engineered manganese (Mn)-based cathode and a new stable solid-state electrolyte, and improve the device energy density by zinc (Zn) anode interface nanotechnology. The success of this project will benefit Australia’s access to new markets and introduce a new low-cost and safe energy storage technology for the long-term viability of Australia’s abundant Zn and Mn resources.Read moreRead less
Photochemical toolkit based on tetracyanoquinodimethane metal-organic semiconducting hybrids. This project aims to develop low-cost light-activated materials for flexible electronics, wearable sensors, antimicrobial fabrics and highly active catalysts. A photochemical toolkit will be developed comprising ultraviolet-active zinc oxide, visible-active metals and visible/infrared-active charge transfer semiconducting materials. Hybridisation of these components will create materials photoactive acr ....Photochemical toolkit based on tetracyanoquinodimethane metal-organic semiconducting hybrids. This project aims to develop low-cost light-activated materials for flexible electronics, wearable sensors, antimicrobial fabrics and highly active catalysts. A photochemical toolkit will be developed comprising ultraviolet-active zinc oxide, visible-active metals and visible/infrared-active charge transfer semiconducting materials. Hybridisation of these components will create materials photoactive across the solar spectrum, leading to photo-redox catalysis and light-activated antimicrobial applications. These materials are expected to lead to cost-effective industrial processes, efficient environmental monitoring, clean-up of industrially-contaminated water streams, infection control in wounds and healthcare settings, and advancing consumer technology platforms.Read moreRead less
Using 3D printing technology to develop architecturally-controlled synthetic bone substitutes. With the ageing population, there is increasing demand for synthetic materials that can regenerate bone. However, purely synthetic bone-substitute biomaterials cannot regenerate large bone defects in weight-bearing conditions due to their fragility. This project aims to develop a customisable, biodegradable, biocompatible and mechanically strong and tough scaffold that overcomes this long-standing prob ....Using 3D printing technology to develop architecturally-controlled synthetic bone substitutes. With the ageing population, there is increasing demand for synthetic materials that can regenerate bone. However, purely synthetic bone-substitute biomaterials cannot regenerate large bone defects in weight-bearing conditions due to their fragility. This project aims to develop a customisable, biodegradable, biocompatible and mechanically strong and tough scaffold that overcomes this long-standing problem. The project aims to achieve this by applying an innovative combination of cutting-edge 3D printing technology, advanced computational modelling and design techniques to produce a next-generation bioceramic scaffold with optimised architecture. This approach aims also to enable the possibility of producing custom-made implants for individual requirements.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100892
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Designing compressible hybrid supercapacitors from graphene aerogels. This project aims to develop high-performance compressible energy storage devices. Compressible hybrid supercapacitors are promising energy storage devices for elastic and wearable electronics under large strain and deformation. However, the controlled fabrication of such devices is challenging. This project aims to design and synthesise compressible hybrid supercapacitors using graphene aerogels as substrates through structur ....Designing compressible hybrid supercapacitors from graphene aerogels. This project aims to develop high-performance compressible energy storage devices. Compressible hybrid supercapacitors are promising energy storage devices for elastic and wearable electronics under large strain and deformation. However, the controlled fabrication of such devices is challenging. This project aims to design and synthesise compressible hybrid supercapacitors using graphene aerogels as substrates through structural design and surface modification. The success of the project will benefit Australia’s booming graphite industry and promote Australian competitiveness in wearable electronics markets.Read moreRead less