Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775692
Funder
Australian Research Council
Funding Amount
$430,000.00
Summary
Micro/nano optomechatronics sensing, measurement, and control research facility. This project aims to establish a facility that enhances the capabilities for sensing, positioning, and manipulating of micro/nano scale objects and environment, and as such constitutes the building block for many frontier technologies such as nanotechnology, bio/nano medicine, microsurgery and neurosurgery, biotechnology, microbiology, microfluidics, and micro/nano manufacturing, all of which are still in their infa ....Micro/nano optomechatronics sensing, measurement, and control research facility. This project aims to establish a facility that enhances the capabilities for sensing, positioning, and manipulating of micro/nano scale objects and environment, and as such constitutes the building block for many frontier technologies such as nanotechnology, bio/nano medicine, microsurgery and neurosurgery, biotechnology, microbiology, microfluidics, and micro/nano manufacturing, all of which are still in their infancy and promise to be the challenging areas of research for the next two decades. The outcomes will strengthen Australia's position in world-class innovative scientific research. It also strengthens collaboration between major engineering institutions and medical experts for innovative research and training of researchers.Read moreRead less
Raman conversion in diamond: Next generation long and far infrared and terahertz lasers. Through the creation of practical and powerful long wave infrared and terahertz lasers, this project will enable more rapid progress in many fields of science and technology, and in important medical, environmental and safeguarding applications of national priority. Australia also stands to benefit economically via commercialization of diamond-based Raman lasers and instruments into the market. The project w ....Raman conversion in diamond: Next generation long and far infrared and terahertz lasers. Through the creation of practical and powerful long wave infrared and terahertz lasers, this project will enable more rapid progress in many fields of science and technology, and in important medical, environmental and safeguarding applications of national priority. Australia also stands to benefit economically via commercialization of diamond-based Raman lasers and instruments into the market. The project will produce highly-trained researchers and students in the theory, design and development of diamond sources, enhance Australia's existing strengths in waveguide optics and photonics, and place Australia at the forefront of research in long-wave infrared and terahertz science.Read moreRead less
Enhanced Mixing Through Particle Motion in Micro-Channels. This study will help place Australia within the forefront of one the key technological endeavours of this century, the development of small-scale microfluidic devices, and, thus, should enable Australian industry to benefit relatively early from these new developments. This new research field seeks to exploit many of the major advances being made in science and engineering. Therefore, the work proposed here clearly addresses the Federal ....Enhanced Mixing Through Particle Motion in Micro-Channels. This study will help place Australia within the forefront of one the key technological endeavours of this century, the development of small-scale microfluidic devices, and, thus, should enable Australian industry to benefit relatively early from these new developments. This new research field seeks to exploit many of the major advances being made in science and engineering. Therefore, the work proposed here clearly addresses the Federal Government's National Research Priority 3, Frontier Technologies for Building and Transforming Australian Industries (priority goals: Breakthrough Science & Frontier Technology). The study will also support the research training of two postgraduate students.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560716
Funder
Australian Research Council
Funding Amount
$864,610.00
Summary
A National T-ray Facility. T-rays are between microwaves and infrared on the electromagnetic spectrum. Recently, advances in femtosecond lasers enabled access to T-ray frequencies, producing an important new imaging modality for non-invasive sensing of materials and structures. Internationally, T-rays represent a rich new science leading to advanced forms of biophotonics, biomedical imaging and spectroscopy. Non-invasive T-ray diagnostics of nano- and bio-materials are being hotly pursued. The o ....A National T-ray Facility. T-rays are between microwaves and infrared on the electromagnetic spectrum. Recently, advances in femtosecond lasers enabled access to T-ray frequencies, producing an important new imaging modality for non-invasive sensing of materials and structures. Internationally, T-rays represent a rich new science leading to advanced forms of biophotonics, biomedical imaging and spectroscopy. Non-invasive T-ray diagnostics of nano- and bio-materials are being hotly pursued. The outcome will be a strategically important Australian T-ray facility that will provide immediate and transparent nationwide access. Historically, industry is transformed every time a new part of the electromagnetic spectrum becomes accessible - T-rays are the next frontier.Read moreRead less
DROP DEFORMATION IN CONFINED MICROFLUIDIC GEOMETRIES. Increasingly, high technology applications in biotechnology and microtechnology industries need to process complex (non-Newtonian) fluids with dispersed particles/droplets in channels as small as several microns (microfluidics). A computational fluid dynamic model of non-Newtonian droplet deformation in microfluidic geometries will be developed, and validated using experimental measurements of the flow field in this project. The aim is to und ....DROP DEFORMATION IN CONFINED MICROFLUIDIC GEOMETRIES. Increasingly, high technology applications in biotechnology and microtechnology industries need to process complex (non-Newtonian) fluids with dispersed particles/droplets in channels as small as several microns (microfluidics). A computational fluid dynamic model of non-Newtonian droplet deformation in microfluidic geometries will be developed, and validated using experimental measurements of the flow field in this project. The aim is to understand and quantify factors influencing droplet deformation. Coupling non-Newtonian characteristics with microfluidic geometries will allow the continuous manufacture of micro-particles of specified size and shape for existing and new applications, and will provide guidance for further extending the process to nano-particle manufacture.Read moreRead less
Electro-viscous effects on pressure-driven liquid flow in microchannels. Australian biotechnology, information technology and food technology industries will benefit from the development of new tailored micro- and nano-fluidic devices for processing of non-Newtonian fluids. The efficiency of functional elements such as valves, pumps, mixers, reactors, heat exchangers can be optimised for specific fluids by understanding the coupling between the fluid properties, the device geometry, surface cha ....Electro-viscous effects on pressure-driven liquid flow in microchannels. Australian biotechnology, information technology and food technology industries will benefit from the development of new tailored micro- and nano-fluidic devices for processing of non-Newtonian fluids. The efficiency of functional elements such as valves, pumps, mixers, reactors, heat exchangers can be optimised for specific fluids by understanding the coupling between the fluid properties, the device geometry, surface charge, and the numerical predictions. This understanding will complement development in related projects on non-Newtonian drop and particle formation in microfluidic flows which envisage continuous particle manufacture for novel materials possessing programmable, enhanced functional properties.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775649
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
An Integrated Multi-Node Microfluidics Facility. The establishment of the proposed facility will enhance Australia's position in microfluidics research, thus contributing to all National Priority areas, particularly the National Priority area 3 through advancement in breakthrough science and frontier technologies. In addition to researchers from participating institutions, the Facility will be made available to other Australian researchers from non-participating organisations at minimum cost. Th ....An Integrated Multi-Node Microfluidics Facility. The establishment of the proposed facility will enhance Australia's position in microfluidics research, thus contributing to all National Priority areas, particularly the National Priority area 3 through advancement in breakthrough science and frontier technologies. In addition to researchers from participating institutions, the Facility will be made available to other Australian researchers from non-participating organisations at minimum cost. The socio-economic potentials of the research carried out using the proposed facility are significant and include: R&D development, small scale high technology manufacture, exports, and improved methods of biochemical processing and medical diagnostics.Read moreRead less
Micro Process Plants - Non-Newtonian flow and particle synthesis in confined geometries. Understanding the flow behaviour of well characterised non-Newtonian fluids within microfluidic and nanofluidic devices is of vital importance to development of novel high-value added services, products and devices within Australia's burgeoning biotechnology, environmental technology, communications and information technology industries. The outcomes of this project will provide new 'systematic' design stand ....Micro Process Plants - Non-Newtonian flow and particle synthesis in confined geometries. Understanding the flow behaviour of well characterised non-Newtonian fluids within microfluidic and nanofluidic devices is of vital importance to development of novel high-value added services, products and devices within Australia's burgeoning biotechnology, environmental technology, communications and information technology industries. The outcomes of this project will provide new 'systematic' design standards for microdevice manufacture for these industries, ultimately leading to the creation of new, exciting avenues for tailoring novel biotechnology and 'point-of-care' products for Australia.Read moreRead less
Simulating two-phase electrodynamic flows in droplet-based microfluidic circuit elements. The knowledge, data and analysis tools developed within this project will facilitate the economical production of electrodynamically controlled integrated droplet-based microfluidic devices for critical high-demand applications such as: genome sequencing; protein evolution, synthesis and crystallisation; micro-structured pharmaceuticals; disposable devices for biomedical analysis; portable point-of-entry (b ....Simulating two-phase electrodynamic flows in droplet-based microfluidic circuit elements. The knowledge, data and analysis tools developed within this project will facilitate the economical production of electrodynamically controlled integrated droplet-based microfluidic devices for critical high-demand applications such as: genome sequencing; protein evolution, synthesis and crystallisation; micro-structured pharmaceuticals; disposable devices for biomedical analysis; portable point-of-entry (biochem)security analysis devices. Hence this project is an investment in enabling technologies to benefit Australia's growing biotech, pharmaceutical and micro/nanotechnology sectors. Tangible community benefits (e.g., in improved diagnostic technologies, pharmaceuticals) will result.Read moreRead less