Blocking of the interfaces of polymeric ion sensors - implications for novel sensor applications. Control of the transmembrane fluxes of polymeric ion sensors represents a paradigm shift that has revolutionised the use of these analytically important devices. This project will develop and characterise innovative methods for controlling these fluxes by using blocked interfaces, and this has important ramifications for the development of robust and reliable sensors, as well as novel biosensors.
Molecular signatures of complex photodissociation reactions. All energy on earth comes from the sun, either directly (e.g photosynthesis) or indirectly (e.g fossil fuels). Photochemistry is the study of how this light is absorbed and what happens to a molecule afterwards. Despite significant experimental and theoretical advances in the past decade (some in our lab), scientists still cannot predict the outcomes of most photochemical reactions. In this project we will determine the reactivity o ....Molecular signatures of complex photodissociation reactions. All energy on earth comes from the sun, either directly (e.g photosynthesis) or indirectly (e.g fossil fuels). Photochemistry is the study of how this light is absorbed and what happens to a molecule afterwards. Despite significant experimental and theoretical advances in the past decade (some in our lab), scientists still cannot predict the outcomes of most photochemical reactions. In this project we will determine the reactivity of several small, fundamental organic molecules. Not only are these molecules pollutants around our cities, but discovery of how they react in the presence of light will allow us to understand and predict the photochemistry of a much wider range of organic species.Read moreRead less
Helium droplets: a nanoscale laboratory for studying intermolecular bonding and chemical reactivity. This type of research requires a rather complicated apparatus capable of creating a stream of helium droplets, embedding molecules and interrogating their properties using laser spectroscopy. The apparatus built in Sydney is the only one capable of this in Australia and using this new apparatus we will create many novel, bizarre and intriguing aggregates of molecules and atoms. The project involv ....Helium droplets: a nanoscale laboratory for studying intermolecular bonding and chemical reactivity. This type of research requires a rather complicated apparatus capable of creating a stream of helium droplets, embedding molecules and interrogating their properties using laser spectroscopy. The apparatus built in Sydney is the only one capable of this in Australia and using this new apparatus we will create many novel, bizarre and intriguing aggregates of molecules and atoms. The project involves cutting-edge scientific methods and will shift the boundaries of can-do science in the laser laboratory at the University of Sydney and in Australia in general.Read moreRead less
New Methods in the Theory and Computational Modelling of Unimolecular and Complex-Forming Bimolecular Reactions. This project will develop new theory and computational methods for the prediction of chemical reaction rates with massively increased efficiency. Complex reactions occurring in combustion which are surprisingly common, but have previously been only poorly understood. The project will make possible the application of detailed statistical and quantum dynamical theories to such complex r ....New Methods in the Theory and Computational Modelling of Unimolecular and Complex-Forming Bimolecular Reactions. This project will develop new theory and computational methods for the prediction of chemical reaction rates with massively increased efficiency. Complex reactions occurring in combustion which are surprisingly common, but have previously been only poorly understood. The project will make possible the application of detailed statistical and quantum dynamical theories to such complex reactions in order to improve the quality of chemical data which is used for modelling atmospheric change and pollution.
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Predicting Environmental Effects on Structure and Reactivity. This project tackles one of the most important and fundamental problems in theoretical chemistry: solvent effects on chemical reactions. The new methods and computer programs generated will be freely available to the Australian (and international) scientific communitities and will further enhance Australia's strong reputation in Theoretical Chemistry.
The applications chosen will allow new technologies in biosensing and strategies in ....Predicting Environmental Effects on Structure and Reactivity. This project tackles one of the most important and fundamental problems in theoretical chemistry: solvent effects on chemical reactions. The new methods and computer programs generated will be freely available to the Australian (and international) scientific communitities and will further enhance Australia's strong reputation in Theoretical Chemistry.
The applications chosen will allow new technologies in biosensing and strategies in computational drug design to be investigated. This will benefit the Australian biotechnology and pharmaceutical industries and may substantially aid in understanding the mechanism and treatment of disease. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100118
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
Nuclear magnetic resonance spectroscopy facilities for the Sydney region. The determination of molecular structure is crucial in the chemical and biomolecular sciences, leading to the development of new drugs and other types of molecules and providing an understanding of how molecules interact with each other. The requested equipment will provide the ability for researchers in the Sydney region to advance our knowledge at this fundamental level by expanding the number and types of experiments th ....Nuclear magnetic resonance spectroscopy facilities for the Sydney region. The determination of molecular structure is crucial in the chemical and biomolecular sciences, leading to the development of new drugs and other types of molecules and providing an understanding of how molecules interact with each other. The requested equipment will provide the ability for researchers in the Sydney region to advance our knowledge at this fundamental level by expanding the number and types of experiments that can be performed.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
Understanding and controlling ion-neutral interactions. Australia faces significant environmental and technological challenges including development of clean, sustainable energy sources and technologies that do not adversely affect the terrestrial atmosphere. This project seeks to facilitate a cleaner, greener future through investigations of fundamental chemical interactions responsible for hydrogen storage in solid media, and atmospheric processes responsible for the production and destruction ....Understanding and controlling ion-neutral interactions. Australia faces significant environmental and technological challenges including development of clean, sustainable energy sources and technologies that do not adversely affect the terrestrial atmosphere. This project seeks to facilitate a cleaner, greener future through investigations of fundamental chemical interactions responsible for hydrogen storage in solid media, and atmospheric processes responsible for the production and destruction of ozone. In both cases, the key interactions between ions and neutral molecules will be elucidated through high-resolution laser studies. Ensuing experimental data will play a crucial role in controlling and predicting ion-neutral interactions in technological and environmental contexts.Read moreRead less
Towards a Microscopic Understanding of Anion Solvation. Atomic and molecular anions are ubiquitous components of oceans, rivers, lakes, and the atmosphere, and serve as key participants in natural and industrial chemical processes. In most situations ions are surrounded by a structured sheath of neutral solvent molecules which profoundly affects their physical and chemical properties. Currently, interactions between anions and solvent molecules are poorly understood. In this project we will use ....Towards a Microscopic Understanding of Anion Solvation. Atomic and molecular anions are ubiquitous components of oceans, rivers, lakes, and the atmosphere, and serve as key participants in natural and industrial chemical processes. In most situations ions are surrounded by a structured sheath of neutral solvent molecules which profoundly affects their physical and chemical properties. Currently, interactions between anions and solvent molecules are poorly understood. In this project we will use lasers to probe clusters consisting of just a few molecules attached to an anion, generating information that will enhance our ability to predict and control chemical processes involved in drug design, salination, atmospheric chemistry, and chemical waste remediation.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100135
Funder
Australian Research Council
Funding Amount
$700,000.00
Summary
Federated single crystal X-ray structural analysis facility. X-ray crystallography is the most widely applied method for the determination of three-dimensional molecular structures. These structures range in size from small systems such as materials and pharmaceuticals through to large biological structures such as proteins. This application will provide a multidisciplinary facility covering the structural characterisation needs of chemistry, pharmacy, biology, and medicine. This will position l ....Federated single crystal X-ray structural analysis facility. X-ray crystallography is the most widely applied method for the determination of three-dimensional molecular structures. These structures range in size from small systems such as materials and pharmaceuticals through to large biological structures such as proteins. This application will provide a multidisciplinary facility covering the structural characterisation needs of chemistry, pharmacy, biology, and medicine. This will position local universities for key scientific breakthroughs that benefit the Australian community by providing improved healthcare technologies, and processes. Furthermore, access to this world-class facility will provide state-of-the-art training for undergraduate, postgraduate and postdoctoral researchers.Read moreRead less