Portable instrument for quantification and genotyping of Cryptosporidium . Cryptosporidium is a parasitic protozoan, causing more than 48,000 deaths in children under 5 and 7.2 million disability-adjusted-life-years globally. A low-cost device that rapidly detects the parasite in drinking and recreational water is needed to enable effective disease management practices. Partnering with Advanced Universal Diagnotik, Seqwater, ALS Water and Gold Coast Water, this project aims to develop a novel de ....Portable instrument for quantification and genotyping of Cryptosporidium . Cryptosporidium is a parasitic protozoan, causing more than 48,000 deaths in children under 5 and 7.2 million disability-adjusted-life-years globally. A low-cost device that rapidly detects the parasite in drinking and recreational water is needed to enable effective disease management practices. Partnering with Advanced Universal Diagnotik, Seqwater, ALS Water and Gold Coast Water, this project aims to develop a novel device, comprising advanced microfluidics and biosensing technology for parasite quantification, genotyping and viability analysis. Expected outcomes are improved Cryptosporidium management, risk prediction, and rapid mitigation of impending outbreaks. The proposed platform has a great potential for detecting other pathogens.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101046
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Ecotoxicology-on-a-chip: towards smart devices in environmental biomonitoring. High-throughput water quality monitoring is of great importance to the wellbeing of Australian society. The project will address this issue by developing new economical miniaturised biocybernetic instrumentation, designed for use by non-specialists and thus applicable for governmental, industrial and community projects.
Silicon-germanium-carbon - a novel opto-mechanic material for optical micro-electromechanical systems. Evolving from past black-and-white images, through present red-green-blue multi-spectral capability, future remote imaging systems promise spectroscopic functionality across much broader wavelength ranges in a low-cost system. However, the high cost of multiple materials and technologies for each specific spectral band limits them to high-cost industry sectors. This project proposes a simple, l ....Silicon-germanium-carbon - a novel opto-mechanic material for optical micro-electromechanical systems. Evolving from past black-and-white images, through present red-green-blue multi-spectral capability, future remote imaging systems promise spectroscopic functionality across much broader wavelength ranges in a low-cost system. However, the high cost of multiple materials and technologies for each specific spectral band limits them to high-cost industry sectors. This project proposes a simple, low-cost, single material technology based on silicon-germanium-carbon thin films for mechanical and optical applications from ultraviolet to long-wave infrared, enabling widespread application of spectroscopic imaging to multiple fields extending from climate change research, through resource exploration, to cancer detection, and aerospace/defense.Read moreRead less
Adaptive multispectral imaging system for remote sensing applications. The many applications of remote sensing include environmental/crop monitoring, oil/mineral exploration, and aerospace/defence. However, remote sensing stands to benefit greatly from infrared spectral imaging devices. This project will develop the technology for an infrared spectral imaging system, suitable for numerous remote sensing applications.
Industrial Transformation Research Hubs - Grant ID: IH180100002
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Research Hub for Driving Farming Productivity and Disease Prevention. The ARC Research Hub for Driving Farming Productivity and Disease Prevention aims to increase farm production and disease prevention through advancing and transferring new artificial intelligence technologies into industrial deployment. The Hub will combine machine vision, machine learning, software quality control, engineering, biology, and farming industries to develop technologies to build more intelligent systems. Thes ....ARC Research Hub for Driving Farming Productivity and Disease Prevention. The ARC Research Hub for Driving Farming Productivity and Disease Prevention aims to increase farm production and disease prevention through advancing and transferring new artificial intelligence technologies into industrial deployment. The Hub will combine machine vision, machine learning, software quality control, engineering, biology, and farming industries to develop technologies to build more intelligent systems. These dynamic systems will help determine what goal to achieve and the most efficient plan to achieve it. This Hub is expected to contribute to higher farming efficiency, lower production costs and fewer disease risks, giving the Australian industry new business opportunities and an international competitive advantage.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100852
Funder
Australian Research Council
Funding Amount
$440,675.00
Summary
High-Performance Monolithic Sensor Technology for Corrosive Environments. Based on my recent discovery on giant thermo-/piezo-resistance, this project aims to enhance fundamental understanding and enable the development of high performance silicon carbide based sensors. The project employs these knowledge advancements to develop new sensors with a sensitivity of thousand-fold larger than that of conventional sensors. The project develops multiple sensors and light harvesting cells to be integr ....High-Performance Monolithic Sensor Technology for Corrosive Environments. Based on my recent discovery on giant thermo-/piezo-resistance, this project aims to enhance fundamental understanding and enable the development of high performance silicon carbide based sensors. The project employs these knowledge advancements to develop new sensors with a sensitivity of thousand-fold larger than that of conventional sensors. The project develops multiple sensors and light harvesting cells to be integrated into a monolithic platform that can function in corrosive environments. The sensor technology can be utilised for monitoring structural health, reducing failure and extending lifetime of structures, providing cutting-edge knowledge to petrochemical and mining industries which are of particular importance to Australia.Read moreRead less
Microcantilevers for multifrequency atomic force microscopy. This project aims to design a microcantilever with high-performing sensors more sensitive and with better noise performance than the typical optical system used in commercial Atomic Force Microscopes (AFMs). The AFM, a nanotechnology instrument, uses a microcantilever (with an extremely shape probe) to interrogate a sample surface. It has made important discoveries in nanotechnology, life sciences, nanomachining, material science and d ....Microcantilevers for multifrequency atomic force microscopy. This project aims to design a microcantilever with high-performing sensors more sensitive and with better noise performance than the typical optical system used in commercial Atomic Force Microscopes (AFMs). The AFM, a nanotechnology instrument, uses a microcantilever (with an extremely shape probe) to interrogate a sample surface. It has made important discoveries in nanotechnology, life sciences, nanomachining, material science and data storage systems. Despite its success, the technique’s spatial resolution and quantitative measurements are limited. This project could lead to breakthrough technologies such as atomic force spectroscopy to study elastic modulus of nanostructures, and establish Australia's prominence in this emerging field.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100228
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Low Temperature Co-fired Ceramic Device Fabrication Facility. Low temperature co-fired ceramic device fabrication facility:
This project seeks to establish a low temperature co-fired ceramics fabrication facility. New kinds of ‘meso-scale’ structurable ceramic processes are filling the technological and dimensional gap between microsystems in silicon and macro microsystems, as the platform can now structure microdevices in the range from a few micrometres to millimetres. This facility would pro ....Low Temperature Co-fired Ceramic Device Fabrication Facility. Low temperature co-fired ceramic device fabrication facility:
This project seeks to establish a low temperature co-fired ceramics fabrication facility. New kinds of ‘meso-scale’ structurable ceramic processes are filling the technological and dimensional gap between microsystems in silicon and macro microsystems, as the platform can now structure microdevices in the range from a few micrometres to millimetres. This facility would provide a resource for Australian researchers to create novel electronic materials and devices that will be key to achieving breakthroughs in micro/nano-technologies and telecommunications. This project expects to support cutting-edge research into multilayer ceramic microsystems such as microelectromechanical systems, wireless sensors and actuators, radio frequency and microwave devices, microfluidic packaging, interfacing and implantation of ultra-fast photoelectrons and acoustic wave devices.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100692
Funder
Australian Research Council
Funding Amount
$420,000.00
Summary
Multiphysics inertial microfluidics: from fundamentals to applications. Separation of particles and particularly cells is an indispensable process in disease diagnostics, chemical/biological assays and food/chemical industries. This project aims to study the interplay between inertial fluid flow, electricity, and magnetism in microscale for particle separation. The project is expected to establish the fundamental theory underpinning the development of the proposed advanced separation technology. ....Multiphysics inertial microfluidics: from fundamentals to applications. Separation of particles and particularly cells is an indispensable process in disease diagnostics, chemical/biological assays and food/chemical industries. This project aims to study the interplay between inertial fluid flow, electricity, and magnetism in microscale for particle separation. The project is expected to establish the fundamental theory underpinning the development of the proposed advanced separation technology. This disruptive technology is expected to enable the unique, high-performance and high-throughput separation of particles such as cells. The technology will potentially benefit the biomedical and pharmaceutical industries, providing economic opportunities and maintaining high-quality healthcare for Australia.Read moreRead less