Response of Proteins to External Non-Ionising Radiation: an Experimental and Computer Modelling Investigation. The expanding use of digital technologies such as mobile phones has led to major health concerns about the effects of non-ionising pulsed radiation exposure which has been shown to produce instantaneous temperature rises undetectable by normal thermometry. The health implications of exposure are not understandable without establishing molecular mechanisms by which pulsed microwaves can ....Response of Proteins to External Non-Ionising Radiation: an Experimental and Computer Modelling Investigation. The expanding use of digital technologies such as mobile phones has led to major health concerns about the effects of non-ionising pulsed radiation exposure which has been shown to produce instantaneous temperature rises undetectable by normal thermometry. The health implications of exposure are not understandable without establishing molecular mechanisms by which pulsed microwaves can cause biological effects. We aim to establish methods for studying the molecular mechanisms of protein structural and energetic changes occurring due to non-ionising radiation. The results will help our industry partner to design specific drugs as well as formulate a scientifically based standard for microwave utilisation.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668520
Funder
Australian Research Council
Funding Amount
$560,000.00
Summary
South Australian Supercluster Facility. This project will maintain and build on existing excellence and strength in areas ranging from computational chemistry, bioinformatics, and plant functional genomics through to water resources management, fluid dynamics and novel fibres and materials for photonics. It will enable the development of cutting edge computational tools and techniques and will maintain and grow strong international links. It will produce graduates of the highest quality able t ....South Australian Supercluster Facility. This project will maintain and build on existing excellence and strength in areas ranging from computational chemistry, bioinformatics, and plant functional genomics through to water resources management, fluid dynamics and novel fibres and materials for photonics. It will enable the development of cutting edge computational tools and techniques and will maintain and grow strong international links. It will produce graduates of the highest quality able to use advanced computing to solve real-world problems. The training provided and the tools and techniques developed will bring major economic benefits and provide excellent links to Australian industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347582
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
South Australian Supercomputing Facility. This grant will fund the construction and installation of a state-of-the-art, heterogeneous supercomputing facility to be named the "South Australian Supercomputing Facility". The facility will be available to all of the State's academic and industrial researchers with advanced high-performance computing needs in a transparent and equitable way. Areas of research excellence to be supported by the facility include but are not limited to: research in comp ....South Australian Supercomputing Facility. This grant will fund the construction and installation of a state-of-the-art, heterogeneous supercomputing facility to be named the "South Australian Supercomputing Facility". The facility will be available to all of the State's academic and industrial researchers with advanced high-performance computing needs in a transparent and equitable way. Areas of research excellence to be supported by the facility include but are not limited to: research in computational physics, computational chemistry, geophysics, computational fluid dynamics, oil and water resource modelling, plant science, bio-informatics, space-environment research, and high-performance, parallel, and grid-based computing.Read moreRead less
Switchable and stereocontrolled photoredox catalysis. This project aims to develop new catalytic synthetic reactions for the rapid and more direct functionalisation of organic compounds under mild conditions with the use of visible light. An integrated experimental and computational approach will be used to design potent visible-light photocatalysts that retain the advantages of standard photoredox catalysis but with the added ability to intercept and, thus control, reactive intermediates in sit ....Switchable and stereocontrolled photoredox catalysis. This project aims to develop new catalytic synthetic reactions for the rapid and more direct functionalisation of organic compounds under mild conditions with the use of visible light. An integrated experimental and computational approach will be used to design potent visible-light photocatalysts that retain the advantages of standard photoredox catalysis but with the added ability to intercept and, thus control, reactive intermediates in situ. This will enable the control of stereochemistry in photoredox reactions – not possible with standard catalysts - and establish other useful synthetic transformations. These strategies will make it easier to prepare valuable classes of organic molecules – efficiently, safely, and cost-effectively.
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Predicting concentration-gradient-driven liquid transport in 2D membranes. This project aims to achieve a predictive understanding of liquid transport through two-dimensional (2D) membranes driven by concentration gradients by using a combination of novel theory and computation. Membranes made from 2D nanomaterials hold great promise for many applications from desalination to power generation to chemical sensing, but the concentration-gradient-driven transport processes that underlie these appli ....Predicting concentration-gradient-driven liquid transport in 2D membranes. This project aims to achieve a predictive understanding of liquid transport through two-dimensional (2D) membranes driven by concentration gradients by using a combination of novel theory and computation. Membranes made from 2D nanomaterials hold great promise for many applications from desalination to power generation to chemical sensing, but the concentration-gradient-driven transport processes that underlie these applications are not well understood. The expected outcome of this project is an unprecedented quantitative understanding of the parameters that control these transport processes. This will enable predictive optimisation of 2D membranes, which will reduce the time and cost of membrane development for diverse applications.
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