Harnessing Interlayer Biexcitons in Atomically Thin Heterostructures. This project aims to investigate the generation of high-quality quantum light sources by harnessing interlayer biexcitons in atomically thin heterostructures. This research expects to expand our understanding of fundamental physics of photon pair generation in atomically thin heterostructures. The expected outcome is demonstration of a prototype light-weight and intense quantum photon source based on novel materials, which can ....Harnessing Interlayer Biexcitons in Atomically Thin Heterostructures. This project aims to investigate the generation of high-quality quantum light sources by harnessing interlayer biexcitons in atomically thin heterostructures. This research expects to expand our understanding of fundamental physics of photon pair generation in atomically thin heterostructures. The expected outcome is demonstration of a prototype light-weight and intense quantum photon source based on novel materials, which can be readily integrated with photonic circuits for quantum communication technologies, enbling the developments of light weight portable devices, such as mobile phones, displays, and wearable photonics. This research could strengthen the development of new industries and lead to job creation in Australia. Read moreRead less
THEORETICAL AND EXPERIMENTAL STUDIES OF CATALYST DOPING AND DEFECTS IN CARBON NANOTUBES FOR HYDROGEN STORAGE. This project aims to develop a fundamental understanding of the adsorption mechanism of hydrogen in carbon nanotubes through theoretical calculations and experimental studies. This addresses an important area of hydrogen storage in nanomaterials such as carbon nanotubes, which promises efficient and clean energy supply in the hydrogen economy in 15-20 years time. Specifically, the proj ....THEORETICAL AND EXPERIMENTAL STUDIES OF CATALYST DOPING AND DEFECTS IN CARBON NANOTUBES FOR HYDROGEN STORAGE. This project aims to develop a fundamental understanding of the adsorption mechanism of hydrogen in carbon nanotubes through theoretical calculations and experimental studies. This addresses an important area of hydrogen storage in nanomaterials such as carbon nanotubes, which promises efficient and clean energy supply in the hydrogen economy in 15-20 years time. Specifically, the project aims to elucidate the effects of catalyst doping and defects in the carbon nanotube walls on the adsorption mechanism and capacity of hydrogen. Such an understanding is crucial to developing the improved carbon nanotubes with high adsorption capacity.Read moreRead less
The investigation of the effects of catalyst doping, element substitution and defects design in carbon materials for hydrogen storage. The successful introduction of an efficient and clean hydrogen economy is contingent on developing a cost-effective storage technology. Carbon materials have demonstrated significant promise in this area. The project aims to investigate the storage capacity of hydrogen in carbon materials by doping catalysts, substituting elements and introducing designed defect ....The investigation of the effects of catalyst doping, element substitution and defects design in carbon materials for hydrogen storage. The successful introduction of an efficient and clean hydrogen economy is contingent on developing a cost-effective storage technology. Carbon materials have demonstrated significant promise in this area. The project aims to investigate the storage capacity of hydrogen in carbon materials by doping catalysts, substituting elements and introducing designed defects into the structures of carbon materials, with both theoretical and experimental methods. This project also aims to foster a long term linkage with the National Institute of Advanced Industrial Science and Technology, Japan thus enhancing Australian Universities's integration with the research institutions overseas in research and developmentRead moreRead less
Development of a molecular flash memory for long-term, extremely high-capacity, unpowered data storage. This collaborative project with INTEL will demonstrate an array of Flash-RAM molecular-memory cells capable, at room temperature, of storing a terabit of data on an area of 2 square mm. This data density is more than four orders of magnitude greater than any commercially available technology and unattainable by conventional silicon-based electronics. We will design and optimize the memory cel ....Development of a molecular flash memory for long-term, extremely high-capacity, unpowered data storage. This collaborative project with INTEL will demonstrate an array of Flash-RAM molecular-memory cells capable, at room temperature, of storing a terabit of data on an area of 2 square mm. This data density is more than four orders of magnitude greater than any commercially available technology and unattainable by conventional silicon-based electronics. We will design and optimize the memory cell, develop the synthesis method, synthesize arrays of the memory cells, and develop new molecular addressing technologies.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL100100099
Funder
Australian Research Council
Funding Amount
$2,340,409.00
Summary
An accelerating journey to the new era of Petabyte optical memory systems. Optical data storage is one of the core aspects of optical information technology which has been globally recognised as one of the next generation high-technology areas that can boost our economy for sustainable development. However, the emergence of blue ray or high-definition DVDs has identified that current optical data storage technology will soon approach the limit of the data storage capacity of approximately 100 Gi ....An accelerating journey to the new era of Petabyte optical memory systems. Optical data storage is one of the core aspects of optical information technology which has been globally recognised as one of the next generation high-technology areas that can boost our economy for sustainable development. However, the emergence of blue ray or high-definition DVDs has identified that current optical data storage technology will soon approach the limit of the data storage capacity of approximately 100 Gigabytes. The ground-breaking Petabyte data storage technology we will research will result in the storage capacity of 10,000 DVDs in one disc and thus underpin every sector of our modern life such as remote education, portable banking, global e-security and telemedicine as well as lead to enormous economic benefits in Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100810
Funder
Australian Research Council
Funding Amount
$343,450.00
Summary
Optical tweezers for bio-nanotechnologies. This project aims to develop a platform of diamond nanosensors and novel optical tweezers for probing cellular processes with single-molecule resolution, in vivo and over physiologically relevant time scales. In biomedicine, long-term imaging of single-molecules is beyond reach with existing bio-labels. The project combines the superior properties of nanodiamond biomarkers (brightness, stability, small size and non-toxicity), with new optical tweezers w ....Optical tweezers for bio-nanotechnologies. This project aims to develop a platform of diamond nanosensors and novel optical tweezers for probing cellular processes with single-molecule resolution, in vivo and over physiologically relevant time scales. In biomedicine, long-term imaging of single-molecules is beyond reach with existing bio-labels. The project combines the superior properties of nanodiamond biomarkers (brightness, stability, small size and non-toxicity), with new optical tweezers which exploit laser trapping of atoms to manipulate nanodiamonds in three-dimensional biological environments. By accessing smaller size and higher force regimes, the platform will improve bio-imaging and bio-manipulation techniques, and potentially advance pathogentracking and early detection of diseases.Read moreRead less
Molecular Electronics Principles and Applications. This project will establish basic conceptual models and computational methods to understand the nature of conduction, memory storage, and solar to electrical energy conversion processes in molecular devices on the 1-nanometer scale. Fundamental research of chemical processes, device interfaces, characterization techniques, and natural photosynthesis will result in widely applicable advances in nanotechnology. Additionally, novel architectures wi ....Molecular Electronics Principles and Applications. This project will establish basic conceptual models and computational methods to understand the nature of conduction, memory storage, and solar to electrical energy conversion processes in molecular devices on the 1-nanometer scale. Fundamental research of chemical processes, device interfaces, characterization techniques, and natural photosynthesis will result in widely applicable advances in nanotechnology. Additionally, novel architectures will be developed for disruptive new technologies in molecular memory and logic design, as well as in the design of biomimetic solar cells. These developments could lead to new Australian electronics industries and an order of magnitude reduction in the production cost of solar electricity.Read moreRead less
Probing and harnessing the light-matter interactions in two-dimensional phosphorene. This project aims to investigate phosphorene, a new two-dimensional material, for the development of new optical and electronic devices. Such materials have unique optical and electronic properties due to their flat physical structure, which gives rise to strong interactions between light and matter. The expected outcome of this project will be new kinds of near infrared light emitting diodes, single photon emit ....Probing and harnessing the light-matter interactions in two-dimensional phosphorene. This project aims to investigate phosphorene, a new two-dimensional material, for the development of new optical and electronic devices. Such materials have unique optical and electronic properties due to their flat physical structure, which gives rise to strong interactions between light and matter. The expected outcome of this project will be new kinds of near infrared light emitting diodes, single photon emitters and ground-breaking lasers. These developments will enable the fabrication of new low-power light sources that can integrate with communication technologies now, and quantum communication technologies in the future.Read moreRead less
Quantum Nanostructure Positioning for Breakthrough Quantum Photonics. The integration of quantum nanostructures in optical devices has been proposed to improve the efficiencies of existing optical devices and create new classes of quantum photonics. Limiting progress is that many nanostructures are made through bottom-up processes with inherently randomly distributions, making integration into devices problematic. Lithographic nanostructure fabrication is rarely an option as it leads to diminish ....Quantum Nanostructure Positioning for Breakthrough Quantum Photonics. The integration of quantum nanostructures in optical devices has been proposed to improve the efficiencies of existing optical devices and create new classes of quantum photonics. Limiting progress is that many nanostructures are made through bottom-up processes with inherently randomly distributions, making integration into devices problematic. Lithographic nanostructure fabrication is rarely an option as it leads to diminishes performance. Here, we propose a new and unique nanostructure positioning technique incorporated directly into the growth process. It interfaces bottom-up technologies with device fabrication, facilitating incorporation of nanostructures in photonic devices, and may be transferrable to a variety of other systems.Read moreRead less
Mapping electronic structure and material properties with atomic resolution. This project will use electron energy loss spectroscopy (EELS) to map the bonding and electronic structure of InGaN quantum wells at the atomic scale. We will measure and correlate the local composition, strain and electronic structure variations within the wells in order to understand the optical emission in this system. The characterisation tools developed will allow us to go beyond measuring structure and composition ....Mapping electronic structure and material properties with atomic resolution. This project will use electron energy loss spectroscopy (EELS) to map the bonding and electronic structure of InGaN quantum wells at the atomic scale. We will measure and correlate the local composition, strain and electronic structure variations within the wells in order to understand the optical emission in this system. The characterisation tools developed will allow us to go beyond measuring structure and composition and map properties of nano-materials at the atomic scale.Read moreRead less