Realisation of an ultra-stable local oscillator using an ultra-low vibration pulse-tube cryocooler. This project will complete the development of a new type of ultra-low-noise ultra-stable microwave oscillator cooled with an ultra-low vibration cryostat and cryocooler. The resulting oscillator will have wide application, but especially to atomic fountain clocks and to very high frequency Very Long Baseline Interferometry (VLBI) radio astronomy.
Understanding graphitization: developing a model for activated carbons. For over 60 years it has remained a puzzle why some carbons graphitise under heating while others do not. The question is of practical importance as oxidation of non-graphitising carbons produces activated carbon, a product of high value with industrial, medical and environmental applications. Using computational and experimental techniques the project will study the graphitisation process and pinpoint the structural element ....Understanding graphitization: developing a model for activated carbons. For over 60 years it has remained a puzzle why some carbons graphitise under heating while others do not. The question is of practical importance as oxidation of non-graphitising carbons produces activated carbon, a product of high value with industrial, medical and environmental applications. Using computational and experimental techniques the project will study the graphitisation process and pinpoint the structural elements which inhibit it. Based on these findings the project aims to develop a nanoscale atomistic model for activated carbons. This is expected to be an important contribution to the field of chemical engineering in which current models of activated carbon neglect either curvature in the network or the presence of oxygen.Read moreRead less
Metamaterials for control of acoustic radiation forces. This project aims to investigate how sound waves exert forces on objects, and how these forces can be controlled by artificially engineered structures known as acoustic metamaterials. The project is expected to lead to a new understanding of acoustic radiation forces, and how they can be efficiently manipulated with high resolution. The expected outcome is a new capability for the measurement of delicate mechanical structures, which avoids ....Metamaterials for control of acoustic radiation forces. This project aims to investigate how sound waves exert forces on objects, and how these forces can be controlled by artificially engineered structures known as acoustic metamaterials. The project is expected to lead to a new understanding of acoustic radiation forces, and how they can be efficiently manipulated with high resolution. The expected outcome is a new capability for the measurement of delicate mechanical structures, which avoids the cost, complexity and side-effects of existing systems. This should benefit many high-tech areas, including inflatable space structures, micro-mechanical sensors and actuators and precise optical components, as well as biological areas such as the study of insect flight and communication.Read moreRead less
Optical tweezers as a micro-rheological probe of soft surfaces. Biomembranes are more than soft containers - their dynamic flexibility plays an important role in cell function, but measurements of mechanical properties of soft surfaces are non-existent. This project develops and applies a new optical tweezers method to measure the flexibility of membranes and its effects upon the friction of nearby particles.
High-load powder dispersion and aerosol delivery: an integrated approach. This project aims to develop a novel design toolbox that can accurately predict dispersion performance of a range of powder systems for high-dose inhaler devices. The project expects to provide the pharmaceutical industry with a cornerstone technology to facilitate the design and optimisation of new powder delivery devices. Outcomes are expected to include new knowledge on powder dispersion behaviour that can be applied to ....High-load powder dispersion and aerosol delivery: an integrated approach. This project aims to develop a novel design toolbox that can accurately predict dispersion performance of a range of powder systems for high-dose inhaler devices. The project expects to provide the pharmaceutical industry with a cornerstone technology to facilitate the design and optimisation of new powder delivery devices. Outcomes are expected to include new knowledge on powder dispersion behaviour that can be applied to various industry sectors, including the environmental, bulk chemical and food industries where the majority of products are in powder form. This knowledge will provide significant benefits to industry through provision of a toolkit that can be used to improve final powder-based product quality.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100136
Funder
Australian Research Council
Funding Amount
$1,100,000.00
Summary
High Performance Solid State NMR Spectroscopy for Materials Research. The project will support research in a diverse set of fields such as biomedical engineering catalysis, energy storage and waste recovery, with cutting edge next-generation solid state (400 MHz) nuclear magnetic resonance capabilities and research expertise. The system enabling high sensitivity, high throughput analysis over extended temperature range will enable addressing of fundamental questions regarding the structure-prope ....High Performance Solid State NMR Spectroscopy for Materials Research. The project will support research in a diverse set of fields such as biomedical engineering catalysis, energy storage and waste recovery, with cutting edge next-generation solid state (400 MHz) nuclear magnetic resonance capabilities and research expertise. The system enabling high sensitivity, high throughput analysis over extended temperature range will enable addressing of fundamental questions regarding the structure-property relationships of advanced functional materials. Accessible to a wide user base in fundamental and applied research, in medicine, energy, catalysis and recycling of waste, the project will extend the current facilities to develop Sydney as regional centre for advanced solid state nuclear magnetic resonance analysis.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100002
Funder
Australian Research Council
Funding Amount
$3,000,000.00
Summary
Australian Partnership in Advanced LIGO+: continuation. The aim of this project is, in collaboration with the USA and UK, to complete the installation and commissioning of the Advanced LIGO+ facilities in the USA in order to bring them to design sensitivity. These facilities expect to increase the event rate of gravitational wave signals by a factor of 125. This should lead to daily detections and the observation of new sources of gravitational waves. Given that only 5% of the universe is detect ....Australian Partnership in Advanced LIGO+: continuation. The aim of this project is, in collaboration with the USA and UK, to complete the installation and commissioning of the Advanced LIGO+ facilities in the USA in order to bring them to design sensitivity. These facilities expect to increase the event rate of gravitational wave signals by a factor of 125. This should lead to daily detections and the observation of new sources of gravitational waves. Given that only 5% of the universe is detectable by telescopes, the impact of gravitational wave detections on our understanding of the universe is inestimable. Australian partnership intends to enable our physicists and astronomers to be at the vanguard of this brand new field and inspire a new generation to study the physical sciences.Read moreRead less
Engineering an artificial protein molecular motor. This project aims to use non-motor protein building blocks to construct an artificial protein motor. Nature already uses nanotechnology as the basis for all its machinery, and uses proteins to construct machines. Each protein component in the motor will have a well-understood function; this artificial protein will elucidate how it converts chemical energy to motion. This process is not understood as molecular motors do not obey the same principl ....Engineering an artificial protein molecular motor. This project aims to use non-motor protein building blocks to construct an artificial protein motor. Nature already uses nanotechnology as the basis for all its machinery, and uses proteins to construct machines. Each protein component in the motor will have a well-understood function; this artificial protein will elucidate how it converts chemical energy to motion. This process is not understood as molecular motors do not obey the same principles as macroscopic machines. Comparing the artificial motor with biological motors will provide insight into the workings of natural motors. This project should lead to molecular motors for nanobiotechnology.Read moreRead less
A novel approach for the real-time measurement of aerosol surface area. This project aims to develop an innovative optical tomography technology capable of direct and real-time measurement of the surface area of airborne particles. By coupling advanced laser diagnostic tools with physiological models and in vitro characterisation techniques, this project will determine the hitherto unknown fundamental and critical relationships between the surface area of an aerosol and its dissolution when deli ....A novel approach for the real-time measurement of aerosol surface area. This project aims to develop an innovative optical tomography technology capable of direct and real-time measurement of the surface area of airborne particles. By coupling advanced laser diagnostic tools with physiological models and in vitro characterisation techniques, this project will determine the hitherto unknown fundamental and critical relationships between the surface area of an aerosol and its dissolution when delivered to a target. The Project’s outcomes will enable aerosol device manufacturers to develop and market significantly more advanced and highly specific products, thus conferring a competitive advantage.Read moreRead less
Particle transport in the human upper airway. This project aims to determine the fundamental mechanisms that drive particle transport in physiologically realistic human airways. Through use of novel magnetic resonance imaging and laser diagnostic techniques, the project expects to transform our ability to develop effective and validated predictive capabilities for particle transport in physiologically accurate geometries. The project outcomes are expected to enable unprecedented definition of ho ....Particle transport in the human upper airway. This project aims to determine the fundamental mechanisms that drive particle transport in physiologically realistic human airways. Through use of novel magnetic resonance imaging and laser diagnostic techniques, the project expects to transform our ability to develop effective and validated predictive capabilities for particle transport in physiologically accurate geometries. The project outcomes are expected to enable unprecedented definition of how particles are transported in human airways as a function of breathing profiles, particle properties and morphology.Read moreRead less