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Integrated approach to self assembled molecular capsules. Process intensification technologies in the form of spinning disc and rotating tube processing are new to Australia and present many opportunities for both carrying out the synthesis of organic compounds and in fabricating nanomaterials. The ensuing nanotechnological applications are more benign in approach then other fabrication techniques, minimising the generation of waste at the same time under continuous flow which is likely to be mo ....Integrated approach to self assembled molecular capsules. Process intensification technologies in the form of spinning disc and rotating tube processing are new to Australia and present many opportunities for both carrying out the synthesis of organic compounds and in fabricating nanomaterials. The ensuing nanotechnological applications are more benign in approach then other fabrication techniques, minimising the generation of waste at the same time under continuous flow which is likely to be more attractive to industry. Proposed applications such as drug delivery, catalysis, smart materials and device technology are expected to foster industrial collaborations. The project will provide first-rate research training and promote Australian science through the development of these new technologies.Read moreRead less
Integrated self assembly processes and spinning disc reactor technology. Spinning Disc Reactor technology is new to Australia and will have wide ranging applications in nano-technology and in developing benign industrial chemical processes with smaller footprint and significantly reduced capital outlay. The cutting edge research will foster collaboration with industry, and lead to establishing new industries in device technology, smart materials, health care products, catalysis and energy storag ....Integrated self assembly processes and spinning disc reactor technology. Spinning Disc Reactor technology is new to Australia and will have wide ranging applications in nano-technology and in developing benign industrial chemical processes with smaller footprint and significantly reduced capital outlay. The cutting edge research will foster collaboration with industry, and lead to establishing new industries in device technology, smart materials, health care products, catalysis and energy storage, through exploiting commercial opportunities. The project will provide excellent research training in a range of scientific skills and in professional development, and will involve overseas PhD exchange programs. The exciting research incorporating benign metrics will enhance public opinion towards science. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882634
Funder
Australian Research Council
Funding Amount
$220,000.00
Summary
Integrated Process Intensification Facility. The new equipment will provide a unique facility for process intensification (PI). No other techniques are capable of controlling features of nano-particles (size, shape, agglomeration, phases and defects) under continuous flow, which is essential for applications in nano-technology. There are unique capabilities of PI in chemical synthesis, including drug development and drug discovery. Overall, applications of PI cover health care products, device t ....Integrated Process Intensification Facility. The new equipment will provide a unique facility for process intensification (PI). No other techniques are capable of controlling features of nano-particles (size, shape, agglomeration, phases and defects) under continuous flow, which is essential for applications in nano-technology. There are unique capabilities of PI in chemical synthesis, including drug development and drug discovery. Overall, applications of PI cover health care products, device technology, and more, for the benefit of the community at large. The facility will foster a more innovative research culture and provide excellent research training at the highest international level, and will provide a platform to foster greater links with industry.Read moreRead less
Cyclophane Carbene Complexes as Catalysts: An Integrated Synthetic, Structural, and Mechanistic Approach. Metal-carbene complexes are emerging as efficient catalysts for chemical processes of immense importance to the pharmaceutical and fine chemicals industries. This project will build on the recent discovery of a family of complexes that exhibits the highest activity yet reported for metal-carbene catalysts in carbon-carbon bond-forming reactions. Insights into the ways the new catalysts work ....Cyclophane Carbene Complexes as Catalysts: An Integrated Synthetic, Structural, and Mechanistic Approach. Metal-carbene complexes are emerging as efficient catalysts for chemical processes of immense importance to the pharmaceutical and fine chemicals industries. This project will build on the recent discovery of a family of complexes that exhibits the highest activity yet reported for metal-carbene catalysts in carbon-carbon bond-forming reactions. Insights into the ways the new catalysts work will be gained through a combination of synthetic, mechanistic, and structural studies. This detailed investigation of structure/reactivity relationships will provide an understanding of why these catalyst are so efficient and hence give synthetic leads for the development of superior new catalysts suitable for industrial application.Read moreRead less
Synthesis and Production of High Value Pyridines Combining the Concepts of Alternative Reaction Media and Process Intensification. This project aims to develop novel syntheses and process route for substituted pyridines by bringing together expertise in the fields of green chemistry and process intensification. Minimisation of waste, energy efficiency, and improved selectivity and control will be the key process and chemistry targets, which will produce high value compounds. Traditional approach ....Synthesis and Production of High Value Pyridines Combining the Concepts of Alternative Reaction Media and Process Intensification. This project aims to develop novel syntheses and process route for substituted pyridines by bringing together expertise in the fields of green chemistry and process intensification. Minimisation of waste, energy efficiency, and improved selectivity and control will be the key process and chemistry targets, which will produce high value compounds. Traditional approaches use organic solvents and preformed salts which are costly, generate waste and the processes are energy intensive due to poor selectivity, low yield and extensive separation steps. This is a generic investigation which will have wide ranging applications in the pharmaceutical, energy and advanced electronic industries.Read moreRead less
Application of process intensification on rotating surfaces (PIRS) in organic synthesis. Process intensification technologies in the form of SDP and RTP are new to Australia and present many opportunities for carrying out the synthesis of organic compounds. They have remarkable versatility in being able to control chemical reactions with greater selectivity than using classical batch technology, at the same time allowing access to new compounds. Moreover, the technologies embrace the principles ....Application of process intensification on rotating surfaces (PIRS) in organic synthesis. Process intensification technologies in the form of SDP and RTP are new to Australia and present many opportunities for carrying out the synthesis of organic compounds. They have remarkable versatility in being able to control chemical reactions with greater selectivity than using classical batch technology, at the same time allowing access to new compounds. Moreover, the technologies embrace the principles of green chemistry in minimising the generation of waste, while operating under continuous flow which is destined to be more attractive to industry. This is likely in the fine chemicals sector, and in drug discovery. The project will provide first-rate research training and promote Australian science. Read moreRead less
The development of tools to study carbohydrate-processing enzymes implicated in human disease. Diseases caused by improper function of carbohydrate-processing enzymes are a major health burden. This research aims to find ways to restore the function of these enzymes bringing a better quality of life to people suffering from these diseases.
Vortex fluidic mediated chemical transformations. This project aims to develop a continuous flow vortex fluidic device (VFD) for chemical and biochemical transformations. Vortex fluidic devices should lead to cleaner and faster ways of preparing complex molecules. Depending on the VFD’s operating parameters, including applying field effects such as Faraday waves, plasmas and light sources, reactions could have higher yields and selectivity than traditional batch processing. This will be translat ....Vortex fluidic mediated chemical transformations. This project aims to develop a continuous flow vortex fluidic device (VFD) for chemical and biochemical transformations. Vortex fluidic devices should lead to cleaner and faster ways of preparing complex molecules. Depending on the VFD’s operating parameters, including applying field effects such as Faraday waves, plasmas and light sources, reactions could have higher yields and selectivity than traditional batch processing. This will be translated into molecular assembly line syntheses in a single unit or a series. Such syntheses should provide a versatile toolbox for molecular transformations, under continuous flow conditions where scalability is addressed upfront. This will be attractive to industry and minimise effects on the environment.Read moreRead less
Modular Vortex Fluidic Mediated Molecular Transformations. The project aims to develop the use of electric and magnetic fields to control chemical and biochemical reactions in high shear thin films under readily scalable continuous flow conditions to then be able to precisely build complex functional molecules. Depending on the orientation, strength and frequency of external electric and magnetic fields, and novel shear stress induced electric fields in solution, rates of reactions can be enhanc ....Modular Vortex Fluidic Mediated Molecular Transformations. The project aims to develop the use of electric and magnetic fields to control chemical and biochemical reactions in high shear thin films under readily scalable continuous flow conditions to then be able to precisely build complex functional molecules. Depending on the orientation, strength and frequency of external electric and magnetic fields, and novel shear stress induced electric fields in solution, rates of reactions can be enhanced, with higher yields and tunable selectivity, and reduced waste and energy usage, which is not possible using traditional batch processing. This will be translated into molecular assembly line processing and the development of a new synthetic toolbox, with applications in preparing pharmaceuticals.
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Design and synthesis of novel lanthanoid complexes for the fabrication of light emitting devices. There is a huge and still growing economy centred around the design and fabrication of low-cost Light Emitting Devices (LEDs), as demonstrated by the excess of US$1.3 billion invested in this field between 2000 and 2007. Nations focused on the production of new and more efficient materials will be at the forefront of these emerging technologies. The major thrust of this proposal, the design and prep ....Design and synthesis of novel lanthanoid complexes for the fabrication of light emitting devices. There is a huge and still growing economy centred around the design and fabrication of low-cost Light Emitting Devices (LEDs), as demonstrated by the excess of US$1.3 billion invested in this field between 2000 and 2007. Nations focused on the production of new and more efficient materials will be at the forefront of these emerging technologies. The major thrust of this proposal, the design and preparation of luminescent rare earths complexes, and their use for the fabrication of LEDS, represent a good opportunity for Australia to access this growing market. Read moreRead less