Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100194
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
Optical diagnostics for the investigation of high-speed energetic processes. Optical diagnostics for the investigation of high-speed energetic processes:
The project seeks to establish equipment to enable the investigation of high-speed energetic processes. Such processes, where large amounts of energy are released over a short time frame, occur in nature and almost every field of science and engineering, and their investigation is a formidable challenge. This challenge is designed to be met th ....Optical diagnostics for the investigation of high-speed energetic processes. Optical diagnostics for the investigation of high-speed energetic processes:
The project seeks to establish equipment to enable the investigation of high-speed energetic processes. Such processes, where large amounts of energy are released over a short time frame, occur in nature and almost every field of science and engineering, and their investigation is a formidable challenge. This challenge is designed to be met through the combined use of state-of-the-art flow visualisation, thermography and spectrometry equipment. These diagnostics would open avenues into so far impossible or difficult to conduct research on highly transient phenomena in various research fields, which include various aspects of fluid mechanics, combustion, and fracture mechanics. The equipment would be instrumental in the design of better and innovative machines, materials, instruments and processes.Read moreRead less
Atomic forces for sorting ultrabright nanodiamonds. This project aims to sort fluorescent nanodiamonds according to their brightness using atomic radiation pressure. Fluorescent nanodiamonds can overcome all limitations associated with conventional fluorescent bio-labels. While readily available, their brightness varies greatly, so a method for yielding high-quality material with consistent brightness is needed. This project combines techniques from laser manipulation of cold atoms and microflui ....Atomic forces for sorting ultrabright nanodiamonds. This project aims to sort fluorescent nanodiamonds according to their brightness using atomic radiation pressure. Fluorescent nanodiamonds can overcome all limitations associated with conventional fluorescent bio-labels. While readily available, their brightness varies greatly, so a method for yielding high-quality material with consistent brightness is needed. This project combines techniques from laser manipulation of cold atoms and microfluidics to create an optofluidic method of particle separation. The proposed device could sort nanodiamonds more than a billion times faster than active sorting techniques. This is expected to lead to better tools for bio-imaging and bio-manipulation.Read moreRead less
Development of mock circulatory system for complex haemodynamic modelling. This project aims to develop a unique mock experimental system to study blood flow dynamics in anatomically realistic coronary artery phantoms. The field of cardiology involves complex fluid dynamic problems, which require the expertise of the fluid dynamics engineer to understand the hemodynamics. Significant innovation in manufacturing and experimental measurement methodologies will be required to develop accurate model ....Development of mock circulatory system for complex haemodynamic modelling. This project aims to develop a unique mock experimental system to study blood flow dynamics in anatomically realistic coronary artery phantoms. The field of cardiology involves complex fluid dynamic problems, which require the expertise of the fluid dynamics engineer to understand the hemodynamics. Significant innovation in manufacturing and experimental measurement methodologies will be required to develop accurate models, which will be designed to allow the partner organisation to undertake further hemodynamic research.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100085
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Micro/Nanofluidic Characterisation Facility. Micro/nanofluidic characterisation facility: Microfluidics promises to enable diagnosis of medical diseases using devices which perform laboratory experiments but on a scale which means the entire system can be hand-held. Whilst the fabrication of miniaturised fluidic channels is well established, the challenge is to bring additional functions onto the chip reducing the reliance on external pumps and electronics. This facility will allow the character ....Micro/Nanofluidic Characterisation Facility. Micro/nanofluidic characterisation facility: Microfluidics promises to enable diagnosis of medical diseases using devices which perform laboratory experiments but on a scale which means the entire system can be hand-held. Whilst the fabrication of miniaturised fluidic channels is well established, the challenge is to bring additional functions onto the chip reducing the reliance on external pumps and electronics. This facility will allow the characterisation of technologies which address on-chip sample preparation using pulsed ultrasonic waves, filtration and pumping using nanofluidic structures, and detection using on-chip circuitry. As such the facility will have the capability to directly address the challenges which must be met to allow diagnosis in rural underprivileged areas. Read moreRead less
Harnessing sperm dynamics in microfluidic sorting technologies. Mammalian reproductive tract is a complex microenvironment that has evolved to select the best sperm for fertilisation using a range of rheological, biochemical and geometrical cues. The project aims to engineer the first multiplexed platform, informed by the natural process, for fully automated and rapid selection of sperm based on all key selection criteria: morphology, swimming behaviour, and DNA integrity. The expected outcome i ....Harnessing sperm dynamics in microfluidic sorting technologies. Mammalian reproductive tract is a complex microenvironment that has evolved to select the best sperm for fertilisation using a range of rheological, biochemical and geometrical cues. The project aims to engineer the first multiplexed platform, informed by the natural process, for fully automated and rapid selection of sperm based on all key selection criteria: morphology, swimming behaviour, and DNA integrity. The expected outcome is the next generation technology for sperm sorting and analysis. This should provide significant benefits, such as new biophysical insights into mammalian reproduction, with potential for future improvement of assisted reproduction technologies – a field in which Australia has a world leading history.Read moreRead less
Dynamic Mechano-Microscopy for use in Mechanobiology . We will develop an innovative microscope that will enable new discoveries in biology. Most microscopes form images of a sample's optical properties, instead we will image a sample's mechanical properties. The reason our novel approach is needed is that cell behaviour depends on the stiffness of it's environment, but current microscopes are unable to image this. Our microscope will provide insights in biology that can improve our understandi ....Dynamic Mechano-Microscopy for use in Mechanobiology . We will develop an innovative microscope that will enable new discoveries in biology. Most microscopes form images of a sample's optical properties, instead we will image a sample's mechanical properties. The reason our novel approach is needed is that cell behaviour depends on the stiffness of it's environment, but current microscopes are unable to image this. Our microscope will provide insights in biology that can improve our understanding of cells, the building blocks of life. We will achieve this by: 1. Developing a microscope that combines microscopic resolution with rapid imaging; 2: Developing the capability to image both within the cell and its surrounding environment; and 3. Using our microscope to make discoveries in biology.Read moreRead less
Acoustic single cell traps: Understanding the woods by examining the trees. This project aims to define the underlying physics behind the manipulation of individual cells in a microfluidic chip using acoustic forces. The technology investigated would offer biomedical researchers a unique capability: that of tracking individual cell responses. It is known for example that drug resistance and latency emerge from small sub-populations of cells, so crucial information is lost when cells are studied ....Acoustic single cell traps: Understanding the woods by examining the trees. This project aims to define the underlying physics behind the manipulation of individual cells in a microfluidic chip using acoustic forces. The technology investigated would offer biomedical researchers a unique capability: that of tracking individual cell responses. It is known for example that drug resistance and latency emerge from small sub-populations of cells, so crucial information is lost when cells are studied at a population level. To trap single cells, the acoustic wavelength excited must be reduced to the order of a cell diameter. By enabling the analysis of different responses due to subtle cell difference, information pertinent to infection pathways and drug response could be gathered.Read moreRead less
Atomic sensors for dark matter, rotation and magnetic fields. This project aims to develop ultra-high-performance sensors. The research will explore new methods for using the magnetic and optical properties of atomic gases to enable multi-parameter sensing without crosstalk between measurements. It is expected that techniques will be developed to allow simultaneous sensing of rotation and magnetic fields using devices that are compact, ultra-precise and energy efficient. It is also anticipated t ....Atomic sensors for dark matter, rotation and magnetic fields. This project aims to develop ultra-high-performance sensors. The research will explore new methods for using the magnetic and optical properties of atomic gases to enable multi-parameter sensing without crosstalk between measurements. It is expected that techniques will be developed to allow simultaneous sensing of rotation and magnetic fields using devices that are compact, ultra-precise and energy efficient. It is also anticipated that these new atomic sensors will support a global network looking for dark matter, which although never seen, is thought to make up 85% of the mass of the universe. The outcomes are expected to benefit medical science, geo-exploration, high-tech manufacturing, navigation and our understanding of the universe.Read moreRead less
Bright x-ray beams from laser-driven microplasmas. This project aims to develop a new generation of bright, laser-like x-ray sources for laboratory use. X-ray sources underpin key diagnostic techniques in materials science, advancing applications from structural engineering through to ore processing and energy storage. However, the limited brightness of present-day laboratory x-ray sources restricts the utility and range of these diagnostic techniques. This research intends to use intense lasers ....Bright x-ray beams from laser-driven microplasmas. This project aims to develop a new generation of bright, laser-like x-ray sources for laboratory use. X-ray sources underpin key diagnostic techniques in materials science, advancing applications from structural engineering through to ore processing and energy storage. However, the limited brightness of present-day laboratory x-ray sources restricts the utility and range of these diagnostic techniques. This research intends to use intense lasers to create microscopic plasmas and drive high harmonic generation. The high harmonic generation process is already used to create laser-like ultraviolet light. By optimising the characteristics of the plasma medium, the project aims to extend bright high harmonic generation to the x-ray regime.Read moreRead less
Nanoparticle radiosensitisation. This project aims to develop new knowledge through a better understanding of physics interactions of particles in compounds with sub-micron size. Research on radiosensitisation by sub-micrometre sized nanoparticles (NPs) is hot worldwide because it could treat cancer, but the physical/physico-chemical/biological mechanism of radiosensitisation is unclear because no physical models describe particle interactions at nanometre scale in solid state nanometre sized ob ....Nanoparticle radiosensitisation. This project aims to develop new knowledge through a better understanding of physics interactions of particles in compounds with sub-micron size. Research on radiosensitisation by sub-micrometre sized nanoparticles (NPs) is hot worldwide because it could treat cancer, but the physical/physico-chemical/biological mechanism of radiosensitisation is unclear because no physical models describe particle interactions at nanometre scale in solid state nanometre sized objects. This project will develop and evaluate specialised physics models to describe particle interactions in NPs and help optimise nanoparticle technology. It will develop expertise in Australia in physics modelling for nanomedicine and other applications of nanotechnology exposed to radiation (e.g. telecommunications, aviation and space).Read moreRead less