Oxide-semiconductor epitaxy: towards next generation nanoelectronics. This project aims to integrate high quality functional oxide heterostructures with semiconductor platforms and address the fundamental obstacles in oxides for highly efficient and high-speed transistor applications by engineering their electronic band structures. The project aims to establish a bridge between the diverse electronic properties of oxides and the established semiconductor platform, and generate new devices and fu ....Oxide-semiconductor epitaxy: towards next generation nanoelectronics. This project aims to integrate high quality functional oxide heterostructures with semiconductor platforms and address the fundamental obstacles in oxides for highly efficient and high-speed transistor applications by engineering their electronic band structures. The project aims to establish a bridge between the diverse electronic properties of oxides and the established semiconductor platform, and generate new devices and functionalities. Expected outcomes include epitaxial functional oxides on Gallium arsenide with ultrahigh, room-temperature sheet electron mobility and a comprehensive understanding of its microscopic origin. This will fundamentally change the route toward novel transistors based on high speed and low energy oxide electronics.Read moreRead less
Quantum Nanophotonics with Atomically Thin Materials . This project aims to deliver new hardware for scalable integrated quantum photonics based on fluorescent defects in hexagonal boron nitride. The project will generate new knowledge in advanced manufacturing of two-dimensional systems, to pivot towards engineering of new optical qubits. Expected outcomes include a solid-state platform for on-chip quantum technologies and development of sovereign quantum capabilities. The results will constitu ....Quantum Nanophotonics with Atomically Thin Materials . This project aims to deliver new hardware for scalable integrated quantum photonics based on fluorescent defects in hexagonal boron nitride. The project will generate new knowledge in advanced manufacturing of two-dimensional systems, to pivot towards engineering of new optical qubits. Expected outcomes include a solid-state platform for on-chip quantum technologies and development of sovereign quantum capabilities. The results will constitute an important step towards implementation of secure communications and quantum information protocols. Benefits include advances in emerging manufacturing capabilities, training of young Australians, generation of intellectual property and securing major economic benefits to all Australians.Read moreRead less
High performance compound semiconductor nanowire optoelectronic devices. Semiconductor nanowires are emerging nano-materials with substantial opportunities for novel photonic and electronic device applications. This project aims at developing a new generation of high performance nanowire-based light-emitting diodes (LEDs), lasers and photodetectors, which will make great contribution to the nation in the areas of science, technology and industry.
Distributed quantum networks with cascaded superconducting circuits. At the heart of all communication is the need to establish strong correlations between remote sites. The non-local character of quantum correlations enables new communication protocols that are impossible with classical resources alone. This project aims to realise a novel class of superconducting devices capable of establishing quantum correlations between distant electronic chips through long-range irreversible interactions. ....Distributed quantum networks with cascaded superconducting circuits. At the heart of all communication is the need to establish strong correlations between remote sites. The non-local character of quantum correlations enables new communication protocols that are impossible with classical resources alone. This project aims to realise a novel class of superconducting devices capable of establishing quantum correlations between distant electronic chips through long-range irreversible interactions. The resulting technology will enable completely new approaches to quantum information processing in superconducting quantum circuits and provide a powerful platform to test the limits of the ability to engineer macroscopic quantum systems.Read moreRead less
Nanostructuring and nanocharacterisation of organic semiconductor devices. This research project will utilise new approaches to pattern organic solar cells on the nanoscale to realise improved efficiencies and improved understanding of device operation. It will also develop soft x-ray techniques to probe the nanostructure of organic semiconductor films with increased chemical and interfacial specificity.
Carbon nanotube based chromatography. This project will reveal new insights into fundamental phenomena of molecular separation processes by carbon nanotubes and underpinning the development of a new generation of microchip separation devices that have the potential to revolutionise chromatographic techniques currently applied in genomics, proteomics, forensics and biotechnology.
Porous Electromaterials for Hydrogen Production and Energy Storage. This project aims to develop nanocomposite electrodes and membranes for efficient production of renewable hydrogen and the next generation of high-energy-density battery technologies. This will be accomplished by the engineering of multi-scale porous materials with tuneable electrical, chemical and morphological properties using earth abundant elements. The intended outcome is the establishment of a scalable methodology for the ....Porous Electromaterials for Hydrogen Production and Energy Storage. This project aims to develop nanocomposite electrodes and membranes for efficient production of renewable hydrogen and the next generation of high-energy-density battery technologies. This will be accomplished by the engineering of multi-scale porous materials with tuneable electrical, chemical and morphological properties using earth abundant elements. The intended outcome is the establishment of a scalable methodology for the structuring and effective integration of microporous materials in highly conductive scaffolds, achieving superior charge and molecular transport, as well as high surface activity. Broad social and economic benefits are anticipated providing new technological solutions for renewable energy storage and fuel production.Read moreRead less
Nanoarchitectonics of carbon nanomaterials. This project aims to develop a generic nanoarchitectonic method to create functional macroscopic carbon architectures using carbon nanomaterials. The project will manipulate the interactions among individual nanostructures by combining bottom-up synthesis with macroscopic wet spinning/knitting or three-dimensional printing assembly processes, leading to functionalities that contrast strongly with conventional nanotechnology. It will demonstrate the tec ....Nanoarchitectonics of carbon nanomaterials. This project aims to develop a generic nanoarchitectonic method to create functional macroscopic carbon architectures using carbon nanomaterials. The project will manipulate the interactions among individual nanostructures by combining bottom-up synthesis with macroscopic wet spinning/knitting or three-dimensional printing assembly processes, leading to functionalities that contrast strongly with conventional nanotechnology. It will demonstrate the technical feasibility of fabric supercapacitors, wearable strain/moisture sensors and carbon membranes. This project is expected to move the fundamental research of nanomaterials to advanced manufacturing techniques.Read moreRead less
Selective area nano-epitaxy. A new major program will be initiated to investigate the epitaxial growth of certain semiconductor nanowires on patterned substrates, without the use of a catalyst. It will result in the ability to produce nanowires of high quality and uniformity. This will lead the way for new and advanced concept nanowire-based devices for future applications.
Antimonide-based nanowires for infra-red and energy applications. This project will investigate and to understand the fundamental growth mechanisms of antimonide-based semiconductor nanowires. It will result in the ability to produce nanowires of high quality and uniformity for applications in infra-red technologies such as photodetectors and solar cells.