The Mechanics of Nanoscale Devices. Australian developments in biosensing, medical diagnostics, clean energy, communication and security technologies, are rapidly growing due to our mounting capacity in nanoscale fabrication. Vital for evolution of next-generation nanodevices is an understanding of how mechanical processes operate at such small scales. This application will contribute to this scientific knowledge base. This will in turn assist Australian industries to progress these applications ....The Mechanics of Nanoscale Devices. Australian developments in biosensing, medical diagnostics, clean energy, communication and security technologies, are rapidly growing due to our mounting capacity in nanoscale fabrication. Vital for evolution of next-generation nanodevices is an understanding of how mechanical processes operate at such small scales. This application will contribute to this scientific knowledge base. This will in turn assist Australian industries to progress these applications and devices, leading to economic, social and technological gains for the Australian community.Read moreRead less
Opto-Microfluidics: A Rapid and Sensitive Platform for Biological Diagnostics. One in four people above 25 years suffer from diabetes-related diseases in Australia, with an associated economic cost exceeding $3 billion a year. A microdevice for continuous glucose monitoring would help patients to manage the disease, leading to huge individual, clinical and societal benefits. Life expectancy is expected to increase along with quality of life. Integration of the microdevice with insulin delivery w ....Opto-Microfluidics: A Rapid and Sensitive Platform for Biological Diagnostics. One in four people above 25 years suffer from diabetes-related diseases in Australia, with an associated economic cost exceeding $3 billion a year. A microdevice for continuous glucose monitoring would help patients to manage the disease, leading to huge individual, clinical and societal benefits. Life expectancy is expected to increase along with quality of life. Integration of the microdevice with insulin delivery would realise an 'artificial pancreas', revolutionising the management and treatment of the disease. The technology will also provide a platform for other point-of-care medical diagnostic devices, which will allow early participation in this emerging market and cement Australia's position in bionanotechnology.Read moreRead less
Lattice Boltzmann method based simulation of complex microchannels and mixing at micro-scales. The proposed study explores fundamental aspects of microfluidics using new tools, which will enhance the country's database of knowledge. It will lead to the development of a low-cost versatile software package, an important tool for solving microfluidics problems of interest to industries and academics, and will facilitate development and optimization of future microdevices. Further, it will improve A ....Lattice Boltzmann method based simulation of complex microchannels and mixing at micro-scales. The proposed study explores fundamental aspects of microfluidics using new tools, which will enhance the country's database of knowledge. It will lead to the development of a low-cost versatile software package, an important tool for solving microfluidics problems of interest to industries and academics, and will facilitate development and optimization of future microdevices. Further, it will improve Australia's competitiveness in the areas of LBM and MEMS both of which are new techniques with promising applications in their respective areas. The project falls under the National Research Priorities areas of Breakthrough Science and Frontier Technology. The potential applications of the technology encompass several key areas.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
Spectroscopy of Complex Fluids in Flow. Complex fluids are composed of polymers and nano-particles in solution. Under flow these fluids may undergo dramatic molecular and nano-particle orientational and spatial ordering that give rise to a fascinating range of rheological behaviour. This project will use state of the art fluorescence spectroscopy which is able to resolve the orientation of single molecules combined with novel rheo-optic methods to characterise flow induced ordering in these flui ....Spectroscopy of Complex Fluids in Flow. Complex fluids are composed of polymers and nano-particles in solution. Under flow these fluids may undergo dramatic molecular and nano-particle orientational and spatial ordering that give rise to a fascinating range of rheological behaviour. This project will use state of the art fluorescence spectroscopy which is able to resolve the orientation of single molecules combined with novel rheo-optic methods to characterise flow induced ordering in these fluids. The flow induced orientation, spatial distribution and nano-particle/macromolecule interactions will be quantified. Theoretical deficiencies in describing complex fluid flow will be reconciled. The experimental insight gained will be exploited to produce novel molecularly ordered materials.
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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
Characterisation and Stability of Thin Electrowetting Films. Electrowetting is of importance to numerous industrial, biomedical and daily life settings such as microfluidic biopharmaceutical applications, coating technology, electronic displays, optical focusing devices, miniaturised chemical analysis systems for homeland security, etc. The work, aimed at generating an understanding of the complex hydrodynamic and physicochemical processes involved, is fundamental research having generic benefit ....Characterisation and Stability of Thin Electrowetting Films. Electrowetting is of importance to numerous industrial, biomedical and daily life settings such as microfluidic biopharmaceutical applications, coating technology, electronic displays, optical focusing devices, miniaturised chemical analysis systems for homeland security, etc. The work, aimed at generating an understanding of the complex hydrodynamic and physicochemical processes involved, is fundamental research having generic benefits to researchers in interfacial science, electrokinetics and microfluidics. The results will also be beneficial to industrial workers in providing engineering protocols for the development of these devices by identifying optimal conditions for fluid manipulation without prone-to-wear mechanical components. Read moreRead less
Feasibility Studies of Using AC Electrospraying for Biomaterials Synthesis. The proposed interdisciplinary research is anticipated to benefit workers in academia and industry as well as clinicians and patients. Given the demand for point-of-care drug delivery, micro/nano-encapsulation and biomaterials synthesis, the research will be beneficial to the pharmaceutical industry and spin-off/start-up microfluidic businesses interested in commercially developing these devices. It is intended that the ....Feasibility Studies of Using AC Electrospraying for Biomaterials Synthesis. The proposed interdisciplinary research is anticipated to benefit workers in academia and industry as well as clinicians and patients. Given the demand for point-of-care drug delivery, micro/nano-encapsulation and biomaterials synthesis, the research will be beneficial to the pharmaceutical industry and spin-off/start-up microfluidic businesses interested in commercially developing these devices. It is intended that the work will improve quality of life by advancing biomaterials technology and by making medical treatment more readily accessable, portable and more efficient. For patients, the proposed drug delivery device can help prevent sudden initial bursts of dose during administration, which could potentially have fatal consequences.Read moreRead less
Supersonic flow past micro-scale particles: Industrial applications. Droplet based materials processing has developed significantly over the last decade, with applications in a wide range of industries where high-strength, light-weight materials are critical. Our research will allow for continued progress of this method, by developing accurate models to predict the cooling rate throughout the process and hence the physical properties of the finished product. Development of this knowledge will al ....Supersonic flow past micro-scale particles: Industrial applications. Droplet based materials processing has developed significantly over the last decade, with applications in a wide range of industries where high-strength, light-weight materials are critical. Our research will allow for continued progress of this method, by developing accurate models to predict the cooling rate throughout the process and hence the physical properties of the finished product. Development of this knowledge will allow for higher precision products to be produced and allow for new techniques to be developed. This information will allow for material processing in Australia to be maintained at world class levels, and for Australian industry to continue to lead the way in the production of technologically advanced materials.Read moreRead less