Investigating Caloric Vestibular Stimulation As A Novel Therapeutic Intervention For Chronic Pain, Mania And Depression.
Funder
National Health and Medical Research Council
Funding Amount
$340,963.00
Summary
Chronic pain, mania and depression are common health problems worldwide and represent an enormous burden of illness. Current treatments may be costly, invasive and have serious side-effects. In the proposed project, demonstration of therapeutic benefit with a novel, simple method of brain stimulation without such limitations could change how these disorders are managed. Moreover, the findings would be of substantial significance in developing countries where treatments are often non-existent.
Using extreme conditions to synthesise new materials. This project aims to synthesise useful materials from non-crystalline light element precursors. Boron, carbon and nitrogen are the hardest known solids, and their ability to form many kinds of chemical bonds offers opportunities for attractive new materials. This project will apply high pressures and temperatures to non-crystalline precursor materials to access previously unobtainable synthesis conditions. This project will create strong and ....Using extreme conditions to synthesise new materials. This project aims to synthesise useful materials from non-crystalline light element precursors. Boron, carbon and nitrogen are the hardest known solids, and their ability to form many kinds of chemical bonds offers opportunities for attractive new materials. This project will apply high pressures and temperatures to non-crystalline precursor materials to access previously unobtainable synthesis conditions. This project will create strong and hard materials with tuneable optical and electronic properties. The expected outcome is new light materials that emit and detect light in the far ultraviolet for biological imaging and tough materials with low friction needed for motors and regenerative technologies.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101129
Funder
Australian Research Council
Funding Amount
$425,948.00
Summary
Two-Dimensional Material Tandem Detectors for Polarimetry and Spectroscopy. The aim of this project is to leverage the fundamental advantages that two-dimensional (2D) materials could provide to vertically-stacked (tandem) photodetectors. The strong absorption, tunable bandgap and polarisation dependence that many 2D materials exhibit, provides a means by which to detect properties of light. This topic is significant because it could overcome current cost/performance issues of tandem detectors, .... Two-Dimensional Material Tandem Detectors for Polarimetry and Spectroscopy. The aim of this project is to leverage the fundamental advantages that two-dimensional (2D) materials could provide to vertically-stacked (tandem) photodetectors. The strong absorption, tunable bandgap and polarisation dependence that many 2D materials exhibit, provides a means by which to detect properties of light. This topic is significant because it could overcome current cost/performance issues of tandem detectors, enabling widespread usage. The expected project outcome is the development of a novel tandem 2D detector, which as a single detector/pixel, can extract the intensity, polarisation and wavelength region of incoming light. This would provide benefits for many future applications, including machine vision and aerial surveying.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150100909
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Metal oxide memristors: Switching phenomena in van der Waals nanostructures. This project aims to integrate two recently researched phenomena: memristors (resistive memory) and planar materials. It aims to adopt atomically thin, planar materials for memristors enabling the realisation of high performance resistive memory devices. The physical and environmental effects that govern the memristive properties, which are of utmost importance in understanding resistive memory nature, will be investiga ....Metal oxide memristors: Switching phenomena in van der Waals nanostructures. This project aims to integrate two recently researched phenomena: memristors (resistive memory) and planar materials. It aims to adopt atomically thin, planar materials for memristors enabling the realisation of high performance resistive memory devices. The physical and environmental effects that govern the memristive properties, which are of utmost importance in understanding resistive memory nature, will be investigated. While generating breakthrough knowledge, the key outcomes of this project will lay the foundation for a novel class of memory devices based on planar van der Waals nanostructures. Such a breakthrough will contribute to the realisation of sustainable memristor technology.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100383
Funder
Australian Research Council
Funding Amount
$450,554.00
Summary
Photothermal management with graphene metamaterials. Environmental and industrial thermal management represents major global energy consumption and CO2 emission. This project aims to investigate a game-changing passive thermal management solution to tackle both heating and cooling problems without using any electricity. This is made possible by designing a nanostructured graphene metamaterial to either totally reject or totally absorb electromagnetic waves in certain spectral ranges. Expected ou ....Photothermal management with graphene metamaterials. Environmental and industrial thermal management represents major global energy consumption and CO2 emission. This project aims to investigate a game-changing passive thermal management solution to tackle both heating and cooling problems without using any electricity. This is made possible by designing a nanostructured graphene metamaterial to either totally reject or totally absorb electromagnetic waves in certain spectral ranges. Expected outcomes include new design and fabrication strategies for novel photothermal films with high performance and cost-effectiveness. This is expected to lead to the development of novel energy efficient technologies for Australian industries, producing direct economic, social and environmental benefits.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190101501
Funder
Australian Research Council
Funding Amount
$408,000.00
Summary
Printed back electrodes enabling low-cost perovskite solar cells. This project aims to address back electrode material, a bottleneck functional material in state-of-the-art perovskite solar cells (PSCs). By engineering printable and conductive materials based on carbon and gold nanowires, the project expects to enable highly-efficient and scalable PSCs while reducing cost of materials and production. These expected outcomes are to be implemented in PSCs and their impact rigorously tested in rese ....Printed back electrodes enabling low-cost perovskite solar cells. This project aims to address back electrode material, a bottleneck functional material in state-of-the-art perovskite solar cells (PSCs). By engineering printable and conductive materials based on carbon and gold nanowires, the project expects to enable highly-efficient and scalable PSCs while reducing cost of materials and production. These expected outcomes are to be implemented in PSCs and their impact rigorously tested in research cells to large-area PSCs modules produced through industry-relevant, scalable, and low-cost printing and coating methods. This will provide significant benefits to Australian industry, from small to medium enterprises to larger utility power companies, while creating economic opportunities and enabling sustainable societies.Read moreRead less
High efficiency dye-sensitised solar cells containing multiple sensitisers. This project aims to develop a new scalable approach suitable for industrial production of high efficiency dye-sensitised solar cells (DSCs) on both glass and flexible polymer substrates. The success of the project would be a breakthrough in DSC technology, bringing the technology a significant step closer to wide-spread commercial applications.
Fast Signal Processing and Control Algorithms for Complex Hierarchical Systems. Complex dynamical behaviour is inherent to many real-world systems including telecommunications networks, financial markets and biological systems. High performance signal processing and control algorithms for such large-scale, complex systems are computationally very expensive in general. An important class of large-scale Markovian models arising in many applications shows a remarkable hierarchical property, display ....Fast Signal Processing and Control Algorithms for Complex Hierarchical Systems. Complex dynamical behaviour is inherent to many real-world systems including telecommunications networks, financial markets and biological systems. High performance signal processing and control algorithms for such large-scale, complex systems are computationally very expensive in general. An important class of large-scale Markovian models arising in many applications shows a remarkable hierarchical property, displaying strong interactions within certain clusters of states and weak interactions among these clusters. By utilizing this property, the proposed project will design and analyze novel reduced-complexity signal processing and control algorithms with rigorous performance guarantees. In addition, this project will explore possibilities of making these algorithms hierarchical such that they are easy to implement through decentralization.Read moreRead less
Towards Distributed Phased Array Radar for High Resolution Weather Monitoring. Several recent reports on climate change by leading international and national bodies forecast that the rate of weather hazards such as storms and wind-shear, and of weather-associated phenomena such as bush fires will increase over the next 40 years. The current technology for monitoring weather events, and effects like wind-shift, which has a serious impact on dangers associated with bush fires, has significant wea ....Towards Distributed Phased Array Radar for High Resolution Weather Monitoring. Several recent reports on climate change by leading international and national bodies forecast that the rate of weather hazards such as storms and wind-shear, and of weather-associated phenomena such as bush fires will increase over the next 40 years. The current technology for monitoring weather events, and effects like wind-shift, which has a serious impact on dangers associated with bush fires, has significant weaknesses. We will deliver considerable improvements in monitoring capability by developing the technology for using a network of small phased array radars. We aim to place monitoring resources where end-user needs are greatest.Read moreRead less
Early Career Industry Fellowships - Grant ID: IE230100467
Funder
Australian Research Council
Funding Amount
$477,237.00
Summary
A More Sustainable High-speed Drive System for Air Conditioning Systems. The project aims to develop an environmentally & strategically sustainable high-speed drive system for the heating, ventilation, and air conditioning (HVAC) systems. A novel rare-earth-less high-speed electric motor (70k rpm) will be designed and experimentally validated. The outcomes will help to mitigate the potential rare earth crisis faced by the HVAC and other industries by significantly reducing the rare earth permane ....A More Sustainable High-speed Drive System for Air Conditioning Systems. The project aims to develop an environmentally & strategically sustainable high-speed drive system for the heating, ventilation, and air conditioning (HVAC) systems. A novel rare-earth-less high-speed electric motor (70k rpm) will be designed and experimentally validated. The outcomes will help to mitigate the potential rare earth crisis faced by the HVAC and other industries by significantly reducing the rare earth permanent magnets used in their drive systems. The design will also enable Conry Tech's HVAC products to use greener refrigerants with extremely low impact on global warming and improve its system efficiency. This project's success will help revive advanced manufacturing of premium HVAC and electric motor products in Australia.Read moreRead less