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
New dielectric materials: Improving storage density of high temperature multilayer ceramic capacitors to sustainably meet future energy demands. Electrical energy generation from renewable sources, such as solar, wind and geothermal, provide enormous potential for meeting future energy demands. However, the ability to store and control this energy for miniaturisation and modularisation in applications requiring a wide temperature usage range is a limiting factor that needs to be addressed. This ....New dielectric materials: Improving storage density of high temperature multilayer ceramic capacitors to sustainably meet future energy demands. Electrical energy generation from renewable sources, such as solar, wind and geothermal, provide enormous potential for meeting future energy demands. However, the ability to store and control this energy for miniaturisation and modularisation in applications requiring a wide temperature usage range is a limiting factor that needs to be addressed. This project aims to develop new bismuth-based lead-free dielectric materials for improving the storage density of high temperature multilayer ceramic capacitors for sustainable applications in the energy and vehicle industries, where high temperature stability and high volumetric efficiency are crucial.Read moreRead less
New high energy density cathode materials for lithium ion batteries. This project aims to develop new high-energy-density and low-cost lithium-rich cathode materials for advanced lithium-ion batteries that can store solar energy for Australian households and power the next generation electric vehicles. The project will design innovative strategies to suppress the voltage decay and capacity decline of the lithium rich materials over long-term cycling. The project expects to significantly improve ....New high energy density cathode materials for lithium ion batteries. This project aims to develop new high-energy-density and low-cost lithium-rich cathode materials for advanced lithium-ion batteries that can store solar energy for Australian households and power the next generation electric vehicles. The project will design innovative strategies to suppress the voltage decay and capacity decline of the lithium rich materials over long-term cycling. The project expects to significantly improve battery performance at a lower price and make a substantial impact to the energy supply technologies and industries in Australia and benefit the environment in the long run.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