Development of modal control systems for adaptive optics. This project will develop a simple, robust and low-cost modal servo system for dynamic control and correction of the propagation and focussing properties of light beams. This new system will incorporate a novel optical sensor, which will be developed in this project, and a new optical corrector being developed at the University of Durham. Currently available astronomical adaptive-optics systems have produced excellent results but are expe ....Development of modal control systems for adaptive optics. This project will develop a simple, robust and low-cost modal servo system for dynamic control and correction of the propagation and focussing properties of light beams. This new system will incorporate a novel optical sensor, which will be developed in this project, and a new optical corrector being developed at the University of Durham. Currently available astronomical adaptive-optics systems have produced excellent results but are expensive and complicated. A low-cost alternative will dramatically increase the use of adaptive optics in industrial, environmental and medical applications. The compensation of distortions in low-cost optical atmospheric sensors will be demonstrated.Read moreRead less
TeraHertz Cell Cluster Imaging. With this program, Australia will benefit from the interaction between physics, engineering, biology and medicine to develop a new TeraHertz imaging system. The project will identify the factors that contribute to TeraHertz contrast in soft tissue cell cultures, thereby developing a non-invasive imaging system to show contrast between diseased and healthy cells. This is a fundamental step towards a system for diagnosing disease states of skin cells, for example, t ....TeraHertz Cell Cluster Imaging. With this program, Australia will benefit from the interaction between physics, engineering, biology and medicine to develop a new TeraHertz imaging system. The project will identify the factors that contribute to TeraHertz contrast in soft tissue cell cultures, thereby developing a non-invasive imaging system to show contrast between diseased and healthy cells. This is a fundamental step towards a system for diagnosing disease states of skin cells, for example, the early detection of melanoma. Ultimately, Australia will benefit from a new technology, and new diagnostic biomedical techniques, for rapid, non-invasive and reliable skin cancer diagnosis.Read moreRead less
Breaking The Wavelength Barrier: Near-Field T-ray Imaging. Australia will benefit from the interaction between engineering, physics, and biology to develop a new T-ray imaging system that will ultimately be able to probe microstructures, biological single cells or even neurons. The project will exploit a powerful new electrooptical technique for obtaining chemical 'fingerprints' at the cellular level. This breakthrough will be a fundamental step towards a system for probing disease states of sin ....Breaking The Wavelength Barrier: Near-Field T-ray Imaging. Australia will benefit from the interaction between engineering, physics, and biology to develop a new T-ray imaging system that will ultimately be able to probe microstructures, biological single cells or even neurons. The project will exploit a powerful new electrooptical technique for obtaining chemical 'fingerprints' at the cellular level. This breakthrough will be a fundamental step towards a system for probing disease states of single cells and will open up new lines of scientific enquiry. Ultimately, Australia will benefit from a new technology and new diagnostic biomedical techniques. This is potentially an enabling technology for future customised medicine, where rapid biochip sensing becomes foreseeable.Read moreRead less
Towards a miniaturised on-chip terahertz biosensing system. Terahertz (or T-ray) radiation is highly sensitive to minute changes in the molecular structure of many substances. Furthermore most packing materials are transparent to this new form of radiation. This implies enormous potential for T-rays in a range of applications from quality control via non-invasive contact-less chemical fingerprinting through to safety and security applications. A detailed study of the molecular vibrations that gi ....Towards a miniaturised on-chip terahertz biosensing system. Terahertz (or T-ray) radiation is highly sensitive to minute changes in the molecular structure of many substances. Furthermore most packing materials are transparent to this new form of radiation. This implies enormous potential for T-rays in a range of applications from quality control via non-invasive contact-less chemical fingerprinting through to safety and security applications. A detailed study of the molecular vibrations that give rise to these fingerprints will help chemists and biologists to learn more about the underlying molecular binding forces, impacting on wide applications for safe non-invasive sensing in the medical, security, chemical and food industries.Read moreRead less
Frequency Domain Micro-Reflection Processing for Pipe Condition Assessment. Over the coming years many millions of dollars will be spent on upgrading deteriorated pipeline infrastructure that is part of water distribution systems all over Australia. Determining the condition of buried pipes is very difficult and expensive. This research will solve that problem. We will develop powerful numerical methods for non-invasive pipe condition assessment. Small controlled transients will be input by a ....Frequency Domain Micro-Reflection Processing for Pipe Condition Assessment. Over the coming years many millions of dollars will be spent on upgrading deteriorated pipeline infrastructure that is part of water distribution systems all over Australia. Determining the condition of buried pipes is very difficult and expensive. This research will solve that problem. We will develop powerful numerical methods for non-invasive pipe condition assessment. Small controlled transients will be input by a specially designed signal generation device that can determine the condition of the inside of the pipe. These new techniques will be cost-effective, accurate and able to cover very long distances of pipe. Water authorities will then be able to quickly decide which sections of pipe require further investigation.Read moreRead less
Micro-reflections for pipe condition assessment in water networks. Maintaining highly reliable water supply pipeline infrastructure for cities, towns and in rural Australia is extremely important. Our research will develop new non-invasive condition assessment techniques. Transient events will be used to create pressure waves that travel up and down a pipe. Sophisticated analysis of the micro-reflections in the measured pressure traces will be the heart of the new techniques. Water utility manag ....Micro-reflections for pipe condition assessment in water networks. Maintaining highly reliable water supply pipeline infrastructure for cities, towns and in rural Australia is extremely important. Our research will develop new non-invasive condition assessment techniques. Transient events will be used to create pressure waves that travel up and down a pipe. Sophisticated analysis of the micro-reflections in the measured pressure traces will be the heart of the new techniques. Water utility managers will be able to make a detailed assessment of the interior pipe wall to determine if significant corrosion or deterioration of the cement mortar lining has occurred. Rehabilitation strategies can then be determined. These new techniques will replace camera inspections that are extremely invasive and expensive.Read moreRead less
Terahertz Metamaterials for Molecular Sensing. Metamaterials are fascinating new man-made structures that can manipulate beams of light in surprising ways; eg. metamaterials are being studied as 'cloaking devices' to render objects invisible. Our proposal aims for fundamental studies and improvement of metamaterials operating in the terahertz (T-ray) frequency regime. The outcome will be the exploitation of new metamaterial devices for high performance molecular sensors and electromagnetic filte ....Terahertz Metamaterials for Molecular Sensing. Metamaterials are fascinating new man-made structures that can manipulate beams of light in surprising ways; eg. metamaterials are being studied as 'cloaking devices' to render objects invisible. Our proposal aims for fundamental studies and improvement of metamaterials operating in the terahertz (T-ray) frequency regime. The outcome will be the exploitation of new metamaterial devices for high performance molecular sensors and electromagnetic filters operating at terahertz frequencies. Socioeconomic benefits to Australia include: (i) increased knowledge-base in metamaterials operating in the terahertz range; (ii) the underpinning of applications in biophotonics and communications; and (iii) commercialisation of novel terahertz devices.Read moreRead less
Beyond the diffraction limit: sub-diffraction T-ray biochip sensing using planar metamaterials. T-rays are able to detect small changes in molecular structure and different isomeric and intermolecular configurations. With a comparatively long wavelength (0.3 mm at 1 THz), diffraction limits its use for imaging small biosamples. A method for achieving sub-diffraction sensing, required for biochips, is to adopt near-field techniques. However, due to the small biosample masses, there is a critical ....Beyond the diffraction limit: sub-diffraction T-ray biochip sensing using planar metamaterials. T-rays are able to detect small changes in molecular structure and different isomeric and intermolecular configurations. With a comparatively long wavelength (0.3 mm at 1 THz), diffraction limits its use for imaging small biosamples. A method for achieving sub-diffraction sensing, required for biochips, is to adopt near-field techniques. However, due to the small biosample masses, there is a critical need to enhance the response. This project will investigate a planar metamaterial thin-film T-ray sensor, for a new leap in non-invasive biochip sensing. This outcome will build downstream IP for rapid screening of DNA and proteins for healthcare. The project will also elucidate the science of T-ray interaction with biomaterials at small scales.Read moreRead less
Dynamic terahertz superlenses for sub-wavelength sensing and imaging. We propose to develop a 'dynamic terahertz superlens' that will dramatically enhance the performance of existing T-ray imaging systems used for biosensing of cells, DNA and proteins. The science of the superlens is remarkable in that it enables image resolution shorter than the wavelength.
Quantitative multi-modal optical imaging of deep tissue. This project aims to create new tools to quantify the structural and functional properties of tissue. Combining multiple optical imaging technologies (multi-modal) into a single, miniaturised probe, these tools could enable physiologists and biomedical researchers to obtain new insight into disease. Encasing the highly miniaturised probe within a medical needle is aimed to allow insertion of the 'needle probe' deep into tissue, extending o ....Quantitative multi-modal optical imaging of deep tissue. This project aims to create new tools to quantify the structural and functional properties of tissue. Combining multiple optical imaging technologies (multi-modal) into a single, miniaturised probe, these tools could enable physiologists and biomedical researchers to obtain new insight into disease. Encasing the highly miniaturised probe within a medical needle is aimed to allow insertion of the 'needle probe' deep into tissue, extending optical imaging to areas not previously accessible. The project could develop novel quantification models to allow longitudinal assessment and comparison between subjects. Validating the tools with specific biomarkers, it could provide outcomes in breast and liver cancer, and a framework to explore other diseases.Read moreRead less