A Method to Characterise an Aberration-Corrected Electron Wave Field - a step towards quantitative electron microscopy. Australia has recently invested in a powerful, new electron microscope, one of the first in the world, which can image features at the atomic scale that could not be seen before. This project will forge a strategic partnership with the designer and the distributor of this microscope, to develop special new methods that will further increase the microscope's imaging power. This ....A Method to Characterise an Aberration-Corrected Electron Wave Field - a step towards quantitative electron microscopy. Australia has recently invested in a powerful, new electron microscope, one of the first in the world, which can image features at the atomic scale that could not be seen before. This project will forge a strategic partnership with the designer and the distributor of this microscope, to develop special new methods that will further increase the microscope's imaging power. This will give Australian scientists unique capabilities with which to investigate and engineer new materials for advanced technological applications and it will train young Australian scientists in these cutting-edge techniques.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775590
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
A single crystal X-ray diffractometer with CCD detector for structural analysis of small molecules. In recent years their have been major advances in the capacity of instrumentation to determine the crystal and molecular structure of chemical compounds and materials which in turn has resulted in a rapidly growing understanding of the relationship between the structure of molecules and their function in the design of new materials and as drugs for the treatment of disease and pain. This infrastr ....A single crystal X-ray diffractometer with CCD detector for structural analysis of small molecules. In recent years their have been major advances in the capacity of instrumentation to determine the crystal and molecular structure of chemical compounds and materials which in turn has resulted in a rapidly growing understanding of the relationship between the structure of molecules and their function in the design of new materials and as drugs for the treatment of disease and pain. This infrastructure also provides training of an international standard for undergraduate and post graduate students, thus building the skills capabilities of Australian scientists in the workforce.Read moreRead less
A reliable physical model of molecular motion in crystals. The scientific benefits would flow, in the first instance, to the large national and international communities of scientists whose research makes use of the results of X-ray diffraction experiments. Applications of the research to amino acids and peptides will benefit investigations into the structure and molecular dynamics of biological systems, including proteins and enzymes. Studies of charge densities in crystals will obtain a standa ....A reliable physical model of molecular motion in crystals. The scientific benefits would flow, in the first instance, to the large national and international communities of scientists whose research makes use of the results of X-ray diffraction experiments. Applications of the research to amino acids and peptides will benefit investigations into the structure and molecular dynamics of biological systems, including proteins and enzymes. Studies of charge densities in crystals will obtain a standard tool for improved modelling of molecular motion, resulting in physically more realistic charge density functions, and hence greater insight into the relationship between properties of crystals and their constituent molecules.Read moreRead less
Control of the Enantiomeric Self-Resolution Process. The availability of enantiopure molecules is crucial in chemistry and medicine. Enantiomeric self-resolution on crystallisation provides pure left- and right-handed molecules from 1:1 mixtures of the two. It is the simplest and cheapest means of obtaining enantiopure molecules, but its occurrence in any given case cannot normally be
predicted. The understanding and control of the self-resolution process gained through this project will repre ....Control of the Enantiomeric Self-Resolution Process. The availability of enantiopure molecules is crucial in chemistry and medicine. Enantiomeric self-resolution on crystallisation provides pure left- and right-handed molecules from 1:1 mixtures of the two. It is the simplest and cheapest means of obtaining enantiopure molecules, but its occurrence in any given case cannot normally be
predicted. The understanding and control of the self-resolution process gained through this project will represent a major breakthrough in organic and pharmaceutical chemistry. This technological advance will make pure handed molecules available readily and cheaply, thereby allowing chemical, pharmaceutical and biological developments to be made by Australian industry.
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Cooperativity in Spin Crossover Systems: Memory, Magnetism and Microporosity. Spin-crossover centres are a well known form of inorganic electronic switch for which variation of temperature, pressure and irradiation leads to a change in d-electron configuration and therefore changes to structure, colour and magnetism. Here we aim to synthesise and study a wide variety of new spin-crossover systems where cooperativitiy between centres, induced by careful supramolecular design, will lead to molecul ....Cooperativity in Spin Crossover Systems: Memory, Magnetism and Microporosity. Spin-crossover centres are a well known form of inorganic electronic switch for which variation of temperature, pressure and irradiation leads to a change in d-electron configuration and therefore changes to structure, colour and magnetism. Here we aim to synthesise and study a wide variety of new spin-crossover systems where cooperativitiy between centres, induced by careful supramolecular design, will lead to molecules and materials having memory retention, magnetic ordering and/or microporosity. The significance of these aims covers several fundamental questions in the science of electronic systems. We also identify a number of potential nanochemical switching applications for the unique systems proposed.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882576
Funder
Australian Research Council
Funding Amount
$588,000.00
Summary
Polymer Characterization Facility (PCF). Future development of macromolecular and biotechnologies have the potential to revolutionize everyday life. Current applications include plastics for engineering, diagnostic devices for biochemical analysis, polymer therapeutics for drug delivery and prosthesis with specific functions. The proposed facility will provide the analytical tools required to probe and develop advanced materials with application in medicine, agriculture, composites, cosmetics, ....Polymer Characterization Facility (PCF). Future development of macromolecular and biotechnologies have the potential to revolutionize everyday life. Current applications include plastics for engineering, diagnostic devices for biochemical analysis, polymer therapeutics for drug delivery and prosthesis with specific functions. The proposed facility will provide the analytical tools required to probe and develop advanced materials with application in medicine, agriculture, composites, cosmetics, communications and electronics.Read moreRead less
Development of metal probes for the selective recognition of DNA. Transition metal complexes with large aromatic ligands have recently been shown to bind DNA by intercalation. However, controversy continues over their base sequence and groove selectivity. We will synthesise a range of chiral metal complexes and screen these against combinatorial oligonucleotide libraries to determine their base sequence selectivity. The information obtained will help us design better intercalators that can be us ....Development of metal probes for the selective recognition of DNA. Transition metal complexes with large aromatic ligands have recently been shown to bind DNA by intercalation. However, controversy continues over their base sequence and groove selectivity. We will synthesise a range of chiral metal complexes and screen these against combinatorial oligonucleotide libraries to determine their base sequence selectivity. The information obtained will help us design better intercalators that can be used as sensitive molecular probes and may find application as antitumour drugs. Binding interaction between the complex and DNA will be studied by NMR spectroscopy.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668439
Funder
Australian Research Council
Funding Amount
$730,000.00
Summary
Elemental and Structural Analysis Facility Comprising a FTICR Mass Spectrometer and a CHNS Analyser. The determination of molecular structure is important in many fields of chemistry, biochemistry and material science. Without such determinations much chemical research would be viewed as incomplete and rendered unpatentable as well as unpublishable. The two state-of-the-art instruments to be purchased will improve the ability of a wide cross-section of researchers to rapidly characterize compoun ....Elemental and Structural Analysis Facility Comprising a FTICR Mass Spectrometer and a CHNS Analyser. The determination of molecular structure is important in many fields of chemistry, biochemistry and material science. Without such determinations much chemical research would be viewed as incomplete and rendered unpatentable as well as unpublishable. The two state-of-the-art instruments to be purchased will improve the ability of a wide cross-section of researchers to rapidly characterize compounds important in fields as varied as medicinal chemistry, material science and geosciences. All types of chemical research, from fundamental to applied, will benefit from these instruments with clear and positive implications regarding societal impact.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0561249
Funder
Australian Research Council
Funding Amount
$651,096.00
Summary
Enhanced X-Ray Analysis and Characterisation Facility. The increasing demand from both academic and industrial sectors has created an urgent need for enhancement and extension of the "Integrated Victorian X-Ray Structural Determination and Materials Characterisation Facility". This proposal achieves this aim by extending the collaborating institutes to include Monash University and adding modern single-crystal, two-dimensional microdiffraction, and wavelength dispersive xrf systems. The result w ....Enhanced X-Ray Analysis and Characterisation Facility. The increasing demand from both academic and industrial sectors has created an urgent need for enhancement and extension of the "Integrated Victorian X-Ray Structural Determination and Materials Characterisation Facility". This proposal achieves this aim by extending the collaborating institutes to include Monash University and adding modern single-crystal, two-dimensional microdiffraction, and wavelength dispersive xrf systems. The result will provide significantly enhanced characterisation and analysis facilities and enable new areas of research to be developed in organic and inorganic synthesis, material chemistry, polymer chemistry, and food, environmental and forensic sciences.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668382
Funder
Australian Research Council
Funding Amount
$1,000,000.00
Summary
e-Research Infrastructure for the Molecular and Materials Structure Sciences. Understanding molecular and materials structure in atomic detail is vital to a knowledge-based economy and a healthy society. The development of smart materials, nanotechnological devices, hydrogen storage materials, molecular switches, magnets and sensors, for example, depends on knowledge of three-dimensional atomic structure. Cures for illnesses such as SARS, AIDS and Alzheimer's disease and understanding the aging ....e-Research Infrastructure for the Molecular and Materials Structure Sciences. Understanding molecular and materials structure in atomic detail is vital to a knowledge-based economy and a healthy society. The development of smart materials, nanotechnological devices, hydrogen storage materials, molecular switches, magnets and sensors, for example, depends on knowledge of three-dimensional atomic structure. Cures for illnesses such as SARS, AIDS and Alzheimer's disease and understanding the aging process depends on knowledge of biomolecular structure. The deployment and development of automation-enhanced remote access to structural instruments through the web will greatly enhance Australian structure-based research, and make this science accessible to the public. Read moreRead less