Special Research Initiatives - Grant ID: SR0354775
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Australian Synchrotron Sciences Network. A synchrotron light source is a critical piece of infrastructure for a modern technological nation. In 2001, the Victorian government announced that it would contribute $157M towards the establishment of a national synchrotron facility, becoming operational in 2007. The research performed at such a facility is exceedingly diverse, and often the underpinning technology is the only point of contact for users. A vibrant and productive facility requires a tra ....Australian Synchrotron Sciences Network. A synchrotron light source is a critical piece of infrastructure for a modern technological nation. In 2001, the Victorian government announced that it would contribute $157M towards the establishment of a national synchrotron facility, becoming operational in 2007. The research performed at such a facility is exceedingly diverse, and often the underpinning technology is the only point of contact for users. A vibrant and productive facility requires a transparent interface between the scientist and the technology. This Network will set up the communication channels within the user base, and between the users and the facility development program.Read moreRead less
Electrochemically, photochemically and magnetically tuneable organic semi-conducting electrodes for probing biologically important redox chemistry and catalysis. Newly developed tuneable, semi-conductor electrode materials will facilitate substantial advances in electrochemistry. The almost unprecedented levels of flexibility with respect to metal and organic constituents will facilitate insights into biologically important electron transfer and coupled catalytic processes and promote commercia ....Electrochemically, photochemically and magnetically tuneable organic semi-conducting electrodes for probing biologically important redox chemistry and catalysis. Newly developed tuneable, semi-conductor electrode materials will facilitate substantial advances in electrochemistry. The almost unprecedented levels of flexibility with respect to metal and organic constituents will facilitate insights into biologically important electron transfer and coupled catalytic processes and promote commercial opportunities for sensor development. Electrochemistry represents an enabling discipline in science. The project offers the opportunity for high quality multi-disciplinary doctoral training, integration of skills of scientists from different backgrounds and opportunities to work in world-class national and international infrastructure in the areas of chemistry, biological chemistry and materials science.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883036
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Integrated Vibrational Spectroscopic Mapping for Archeological, Biological, Geological, Materials, and Medical Research. The expected benefits that will arise will include: green chemical processes with improved environmental and economic impacts; improved treatments and diagnoses of diseases; understanding of fundamental geological processes; identification of the earliest forms; studies of archaeological artefacts; evolution of life on Earth; the design of improved dental materials. Ultimatel ....Integrated Vibrational Spectroscopic Mapping for Archeological, Biological, Geological, Materials, and Medical Research. The expected benefits that will arise will include: green chemical processes with improved environmental and economic impacts; improved treatments and diagnoses of diseases; understanding of fundamental geological processes; identification of the earliest forms; studies of archaeological artefacts; evolution of life on Earth; the design of improved dental materials. Ultimately, this research will include economic and social benefits in; industrial processes; the mining industry; medicine; and dentistry. An understanding of the origin and early evolution of life on Earth also has many social implications.Read moreRead less
Novel Scanning Electrochemical Microscopy applications in molecular, supramolecular electrochemistry and biological systems. Improved understanding of chemical reactivity in natural and artificial molecular systems and acquisition of a wider perspective of electron transfer processes are two important challenges in chemistry and biology. Through this well defined research project, the CI, jointly with the host facility, has the skills to achieve valuable new insights. This project will expand Au ....Novel Scanning Electrochemical Microscopy applications in molecular, supramolecular electrochemistry and biological systems. Improved understanding of chemical reactivity in natural and artificial molecular systems and acquisition of a wider perspective of electron transfer processes are two important challenges in chemistry and biology. Through this well defined research project, the CI, jointly with the host facility, has the skills to achieve valuable new insights. This project will expand Australia's knowledge base and research capability and open new scenarios for frontier technologies and advanced materials. This project will introduce the SECM methods into Australia. The foreseen benefits include technology exchange and contribution to fundamental and applied science.Read moreRead less
Nanoscale Coating and Biomodification of Colloids for Biological Applications. The research entails the preparation of novel biofunctional colloids of nanometer to micrometer dimensions and their utilisation in biological applications. Self-assembly processes will be exploited to achieve nanoscale biomodification of technologically important colloid particles, including latex beads and rare earth and semiconductor nanoparticles. The studies conducted will generate fundamental knowledge pertainin ....Nanoscale Coating and Biomodification of Colloids for Biological Applications. The research entails the preparation of novel biofunctional colloids of nanometer to micrometer dimensions and their utilisation in biological applications. Self-assembly processes will be exploited to achieve nanoscale biomodification of technologically important colloid particles, including latex beads and rare earth and semiconductor nanoparticles. The studies conducted will generate fundamental knowledge pertaining to the underlying factors that govern the formation of biofunctional colloid particles through self-assembly. This is essential for the development of tailored colloids that will meet the demands placed on nanomaterials synthesis and performance by nanotechnology. The colloids prepared will find new applications in medicine, biocatalysis and bioassays.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0238898
Funder
Australian Research Council
Funding Amount
$352,000.00
Summary
Novel Optical Microprobes - fluorescence excitation, lifetime and surface enhanced Raman spectroscopies. State-of-the-art technologies in microscopy will be combined with the versatility and diagnostic power of spectroscopy for the analysis and identification of materials by methods sensitive to chemical structure as well as spatial inhomogeneity. The proposed systems will operate within an existing multi-user optical characterisation facility at Macquarie University thus supporting the research ....Novel Optical Microprobes - fluorescence excitation, lifetime and surface enhanced Raman spectroscopies. State-of-the-art technologies in microscopy will be combined with the versatility and diagnostic power of spectroscopy for the analysis and identification of materials by methods sensitive to chemical structure as well as spatial inhomogeneity. The proposed systems will operate within an existing multi-user optical characterisation facility at Macquarie University thus supporting the research of an established and expanding network of researchers in the Sydney area and in Melbourne. The suite of instruments will provide new and exciting avenues for interdisciplinary research between the physical and biological sciencesRead moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560672
Funder
Australian Research Council
Funding Amount
$202,705.00
Summary
Ultrafast laser facility for chemical, biological and physical investigations of advanced materials. Ultrafast laser techniques are becoming indispensable in many diverse scientific disciplines. Within the Australian scientific community, there is a great need for enhanced access to sophisticated ultrafast laser instrumentation. The expansion to the femtosecond laser facility through the addition of state-of-the-art laser devices, will enable novel laser spectroscopy measurements and advanced op ....Ultrafast laser facility for chemical, biological and physical investigations of advanced materials. Ultrafast laser techniques are becoming indispensable in many diverse scientific disciplines. Within the Australian scientific community, there is a great need for enhanced access to sophisticated ultrafast laser instrumentation. The expansion to the femtosecond laser facility through the addition of state-of-the-art laser devices, will enable novel laser spectroscopy measurements and advanced optical microscopy techniques to be applied to investigations of advanced materials and biological systems. Access to such instrumentation is crucial to fields including photoluminescent conductive polymers, nanoparticles, engineered supramolecules for artificial photosynthetic systems, and photoactivated therapy and drug delivery/release technology.Read moreRead less
Biologically-Inspired Recognition and Processing in Colloidal Systems. The proposed research will enhance the understanding of forces and adsorption in biologically-inspired synthetic systems, and thereby create new strategies for improving selective adsorption, stabilization, coagulation, and separation. The expected outcomes are: increased understanding of chiral interactions at surfaces, a technique for rapid measurement of surface selectivity, new and better agents for chiral separation, a ....Biologically-Inspired Recognition and Processing in Colloidal Systems. The proposed research will enhance the understanding of forces and adsorption in biologically-inspired synthetic systems, and thereby create new strategies for improving selective adsorption, stabilization, coagulation, and separation. The expected outcomes are: increased understanding of chiral interactions at surfaces, a technique for rapid measurement of surface selectivity, new and better agents for chiral separation, a reduction in the use of organic pollutants, new methods for colloidal processing that will enable the preparation of new materials, and new surface coatings for increasing the useful life-time of medical implants.Read moreRead less
Nanoengineered Colloids and thin films through self-assembly with potential applications in Bioscince and Nanotechnology. The proposed research program will focus on the preparation, characterisation and application of novel, small (nanometer size) particles and thin (micrometer thick)films derived from such particles. These new and advanced materials will be prepared by usinf a recently developed, highly versatile and facile technology to coat particles in solution. The strategy to be used en ....Nanoengineered Colloids and thin films through self-assembly with potential applications in Bioscince and Nanotechnology. The proposed research program will focus on the preparation, characterisation and application of novel, small (nanometer size) particles and thin (micrometer thick)films derived from such particles. These new and advanced materials will be prepared by usinf a recently developed, highly versatile and facile technology to coat particles in solution. The strategy to be used entails the step-by-step construction of well-defined layers of different composition on particles and flat surfaces, thereby allowing unprecendented control over the material properties and function. This will provide new avenues for the application of nanoscale materials in biotechnology and nanotechnology.Read moreRead less
A new G-protein coupled receptor target for conotoxins. We aim to understand the interaction between venom components from the marine cone snail, a major source of potential drug leads, and a key receptor in nerve cell signalling. This receptor plays a role in many nervous system functions and has been proposed as a target for treating a range of diseases including pain, depression and drug addiction. It is critical that we understand this interaction so we can fully exploit the potential of the ....A new G-protein coupled receptor target for conotoxins. We aim to understand the interaction between venom components from the marine cone snail, a major source of potential drug leads, and a key receptor in nerve cell signalling. This receptor plays a role in many nervous system functions and has been proposed as a target for treating a range of diseases including pain, depression and drug addiction. It is critical that we understand this interaction so we can fully exploit the potential of these molecules as drug leads. The potential exists for multibillion dollar markets for these new drugs that could provide significant economic benefits to Australia.Read moreRead less