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
Optically-driven micromachines and microtools. The use of optical forces to trap and manipulate microscopic particles has developed from a novelty into a widely used versatile research tool - optical tweezers. New advances, such as the application and optical measurement of optical torque, have been brought to the brink of practical application. We will apply these methods to the development and production of micromachines of unprecedently small size, and the development of new medical diagnosti ....Optically-driven micromachines and microtools. The use of optical forces to trap and manipulate microscopic particles has developed from a novelty into a widely used versatile research tool - optical tweezers. New advances, such as the application and optical measurement of optical torque, have been brought to the brink of practical application. We will apply these methods to the development and production of micromachines of unprecedently small size, and the development of new medical diagnostic techniques, and industrial and research tools.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453320
Funder
Australian Research Council
Funding Amount
$347,886.00
Summary
Advanced Spectroscopy for Nano-characterisation of Materials Chemistry and Properties. This application proposes to establish a cutting-edge spectroscopic facility which includes; electron energy-loss spectroscopy (EELS), energy-dispersive X-ray spectroscopy (EDS), cathodoluminescence (CL), photoluminescence (PL) and micro-Raman spectroscopy. Each of the spectrometers to be installed has significantly higher sensitivity and resolution than any other facility available in Australia and is capable ....Advanced Spectroscopy for Nano-characterisation of Materials Chemistry and Properties. This application proposes to establish a cutting-edge spectroscopic facility which includes; electron energy-loss spectroscopy (EELS), energy-dispersive X-ray spectroscopy (EDS), cathodoluminescence (CL), photoluminescence (PL) and micro-Raman spectroscopy. Each of the spectrometers to be installed has significantly higher sensitivity and resolution than any other facility available in Australia and is capable of full spectrum imaging. This new spectroscopic infrastructure will enable the knowledge-based development of new materials by allowing complete characterisation of structure-composition-property relationships at the nanometre level.Read moreRead less
A new nano-sensor technology for the detection and identification of residual vapours of explosives, drugs and chemicals in the air. Fighting terrorism and crime is one of the most important and difficult tasks that requires substantial human and technological resources. This project will help to address this enormous problem by developing a new optical sensor technology for the detection and identification of traces of chemicals, explosives, drugs and biological agents. It will develop a labora ....A new nano-sensor technology for the detection and identification of residual vapours of explosives, drugs and chemicals in the air. Fighting terrorism and crime is one of the most important and difficult tasks that requires substantial human and technological resources. This project will help to address this enormous problem by developing a new optical sensor technology for the detection and identification of traces of chemicals, explosives, drugs and biological agents. It will develop a laboratory prototype of this sensor that is expected to have superior sensitivity and operational capabilities. Thus it will noticeably contribute to practical law enforcement, air quality and environmental monitoring, counter-terrorism, air safety, border security and customs service. It will also lead to further development of nano-optics and nanotechnology in Australia. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100848
Funder
Australian Research Council
Funding Amount
$437,299.00
Summary
Quantum control of sound with light. This project aims to build the first photonic architecture capable of controlling the quantum properties of acoustic waves travelling in crystalline materials and quantum fluids. This level of control is expected to herald new capabilities in sensing applications, quantum information and quantum computing. The project seeks to develop a silicon-based photonic platform that enables the preparation of non-classical states of sound within superfluid helium. This ....Quantum control of sound with light. This project aims to build the first photonic architecture capable of controlling the quantum properties of acoustic waves travelling in crystalline materials and quantum fluids. This level of control is expected to herald new capabilities in sensing applications, quantum information and quantum computing. The project seeks to develop a silicon-based photonic platform that enables the preparation of non-classical states of sound within superfluid helium. This new platform will also be used to develop an ultra-compact silicon-chip based laser. The project outcomes should provide a deeper understanding of quantum fluids and quantum mechanics, and enable the realisation of new quantum technologies with substantial commercialisation potential.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100318
Funder
Australian Research Council
Funding Amount
$368,554.00
Summary
Superfluid optomechanics with quantised vortices. This project aims to develop new technologies to probe and control the flow of superfluid helium at size-scales never before possible. Superfluid helium is the only quantum liquid, characterised by flow without dissipation and quantised vortices. Leveraging the techniques of cavity optomechanics, this project aims to demonstrate control of superfluid helium properties at the quantum level, including the first demonstration of laser-cooling of a l ....Superfluid optomechanics with quantised vortices. This project aims to develop new technologies to probe and control the flow of superfluid helium at size-scales never before possible. Superfluid helium is the only quantum liquid, characterised by flow without dissipation and quantised vortices. Leveraging the techniques of cavity optomechanics, this project aims to demonstrate control of superfluid helium properties at the quantum level, including the first demonstration of laser-cooling of a liquid into its quantum ground-state. The devices developed in this project will also serve as probes of unprecedented sensitivity for the study of 2D superfluid helium. The new technologies developed will have potential for broad uptake in the scientific community and generation of intellectual property and patents for quantum technology and inertial sensors.Read moreRead less
Scalable nanomechanical information processing. This project aims to build the first scalable computer architecture based on nanoscale motion on a silicon chip. Such nanomechanical computers could extend computing performance in space and earth-orbit applications, and in other environments where intense radiation causes digital electronics to fail. The project intends to utilise recent advances in nanomechanics and nanofabrication to demonstrate all key nanomechanical circuit elements, including ....Scalable nanomechanical information processing. This project aims to build the first scalable computer architecture based on nanoscale motion on a silicon chip. Such nanomechanical computers could extend computing performance in space and earth-orbit applications, and in other environments where intense radiation causes digital electronics to fail. The project intends to utilise recent advances in nanomechanics and nanofabrication to demonstrate all key nanomechanical circuit elements, including transistors, logic gates, memories and analogue-to-digital converters and to deliver a roadmap for commercialisation of the technology in Australia. The expected outcome of this project is the development of the underpinning nanotechnologies, predicted to have wide uses in sensing, health and communications,and which could improve heat management and energy efficiency in future computers. This new approach to computing has potential for near-term commercial impact in the aerospace industry, building on Australian know-how.Read moreRead less
Scalable and reversible computing with integrated nanomechanics. This project aims to build the first scalable computing architecture based on nanomechanical motion, integrated on a silicon chip and proven in harsh environments. This could extend the performance of computers in space and high-radiation environments, e.g. allowing robust satellite stabilisation. The project will leverage our know-how in phononics and nanofabrication to enable previously unprecedented control of nanomechanical mot ....Scalable and reversible computing with integrated nanomechanics. This project aims to build the first scalable computing architecture based on nanomechanical motion, integrated on a silicon chip and proven in harsh environments. This could extend the performance of computers in space and high-radiation environments, e.g. allowing robust satellite stabilisation. The project will leverage our know-how in phononics and nanofabrication to enable previously unprecedented control of nanomechanical motion, and exquisitely low energy dissipation. It aims to construct a nanomechanical processor capable of digital servo control, built from nanomechanical waveguides, transistors, logic gates and analogue-to-digital converters. It will also develop reversible logic gates, a key step towards ultralow-power computing.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882224
Funder
Australian Research Council
Funding Amount
$440,000.00
Summary
Vector Magnetic Field Facility for Nanoscale Spintronic Materials and Device Research. Electronic devices underpin a trillion dollar industry worldwide and are an essential part of modern life. Spintronics (spin-electronics) is an emergent technology that combines the electrical and magnetic properties of electrons to represent and process information. Spintronic chips are expected to be fast, versatile, capable of simultaneous data storage and processing, while at the same time consuming less ....Vector Magnetic Field Facility for Nanoscale Spintronic Materials and Device Research. Electronic devices underpin a trillion dollar industry worldwide and are an essential part of modern life. Spintronics (spin-electronics) is an emergent technology that combines the electrical and magnetic properties of electrons to represent and process information. Spintronic chips are expected to be fast, versatile, capable of simultaneous data storage and processing, while at the same time consuming less energy. Industry analysts suggest the spintronic market will exceed $10 billion. This facility will provide the critical infrastructure needed to study the electronic and magnetic properties of nanostructured materials, providing the underpinning knowledge to develop the next generation of spintronic devices.Read moreRead less