The elusive upper bound of heat transfer in horizontal convection. The question as to whether lateral variation in global ocean buoyancy resulting from low solar radiation near the poles and higher temperatures in the tropical regions (known as horizontal convection) is a driver for global ocean currents is critical to our understanding of this complex and delicate system that maintains Earth's temperate climate. This question hinges on the relationship between heat transport and strength of buo ....The elusive upper bound of heat transfer in horizontal convection. The question as to whether lateral variation in global ocean buoyancy resulting from low solar radiation near the poles and higher temperatures in the tropical regions (known as horizontal convection) is a driver for global ocean currents is critical to our understanding of this complex and delicate system that maintains Earth's temperate climate. This question hinges on the relationship between heat transport and strength of buoyancy forcing towards global scales; this project proposes a landmark experimental effort supported by detailed simulations to probe the ultimate regime of heat transport in horizontal convection. The project is expected to inform the direction of future ocean and climate modelling efforts to the benefit of humanity.Read moreRead less
Computational Nanofluidics. This project will generate an increased level of skill and expertise in Australia in the emerging science of nanotechnology. To realise the promise of nanotechnology, a means of controlled propulsion on the nano scale is vital. A deeper understanding of nanofluidics that allows greater predictive capacities can greatly aid this realisation. It is highly likely that computational nanofluidics will play as important a role in nanotechnology based industries as computat ....Computational Nanofluidics. This project will generate an increased level of skill and expertise in Australia in the emerging science of nanotechnology. To realise the promise of nanotechnology, a means of controlled propulsion on the nano scale is vital. A deeper understanding of nanofluidics that allows greater predictive capacities can greatly aid this realisation. It is highly likely that computational nanofluidics will play as important a role in nanotechnology based industries as computational fluid dynamics (CFD) currently plays in today's manufacturing, automotive and aerospace industries. The skills and knowledge gained from this project will enhance our international competitiveness in this area. Read moreRead less
Substance abuse is a significant social and economic burden upon Australian societies and on societies around the world. Treatment remains problematic due to the multi-layer nature of the disease, difficulties with treatment compliance and less than ideal treatment regimes. The present study aims to improve treatments for alcohol and drug abuse using pre-clinical models to identify and characterize a new brain system implicated in drug-seeking.
High Penetrance Deleterious Mutations In Blinding Glaucoma
Funder
National Health and Medical Research Council
Funding Amount
$1,345,055.00
Summary
This project aims to identify the genes most commonly mutated in individuals with advanced glaucoma. Identification of such genes will lead to improved understanding of glaucoma pathogenesis, a better ability to predict risk, and the identification of drug targets for novel therapies.
Salt (sodium) is an essential electrolyte. Our convincing and complementary findings provide compelling evidence for a link between evolutionarily ancient “instincts” and substance abuse. This proposal is translational, including studies in opiate dependent humans. Our studies will establish how and where in the brain endogenous opioids are implicated in the gratification of salt appetite, how salt appetite is altered in opiate dependency and if salt appetite recovers following opiate withdrawal
Accurate quantum modeling of the van der Waals interaction and its application to molecular physisorption onto surfaces. Developing zero emission clean fuel technology for transportation and developing sensitive diagnostic markers for medical diagnosis will clearly benefit Australia. In both cases large technological challenges need to be overcome. This investigation will provide theoretical insight and understanding into the molecular processes which underpin these highly desirable technologies ....Accurate quantum modeling of the van der Waals interaction and its application to molecular physisorption onto surfaces. Developing zero emission clean fuel technology for transportation and developing sensitive diagnostic markers for medical diagnosis will clearly benefit Australia. In both cases large technological challenges need to be overcome. This investigation will provide theoretical insight and understanding into the molecular processes which underpin these highly desirable technologies and aid scientists and engineers in their development. A further, more general, outcome will be an accurate and predictive methodology for investigating nanotechnology problems in any material where molecular physisorption is an important process.Read moreRead less
Fundamental Theoretical Study of Hydrogen Interactions with Novel Nanostructures. While governments around the world are planning to implement a hydrogen-based energy economy in the next several decades, the delivery of practical hydrogen energy technology has proven elusive to date, with major developments required in the production, storage and transport of hydrogen. This research will undertake to provide one key step in the development of safe and efficient hydrogen storage, namely a fundam ....Fundamental Theoretical Study of Hydrogen Interactions with Novel Nanostructures. While governments around the world are planning to implement a hydrogen-based energy economy in the next several decades, the delivery of practical hydrogen energy technology has proven elusive to date, with major developments required in the production, storage and transport of hydrogen. This research will undertake to provide one key step in the development of safe and efficient hydrogen storage, namely a fundamental study delivering basic knowledge of hydrogen interactions with nano-structured materials constructed from inexpensive light metals such as Aluminium.Read moreRead less
Understanding and controlling the processes underlying self assembly of nanostructures on surfaces. Efficient clean fuel technology, new classes of nano- and bio-materials, bio specific drug delivery systems, efficient environmental remediation technologies, advanced catalytic applications, namely every area of technology would benefit from the ability to control self-assembly of matter at the atomic level during fabrication of nanodevices. This proposal seeks to understand the processes driving ....Understanding and controlling the processes underlying self assembly of nanostructures on surfaces. Efficient clean fuel technology, new classes of nano- and bio-materials, bio specific drug delivery systems, efficient environmental remediation technologies, advanced catalytic applications, namely every area of technology would benefit from the ability to control self-assembly of matter at the atomic level during fabrication of nanodevices. This proposal seeks to understand the processes driving self-assembly of nanomaterials and how to control these processes.Read moreRead less
To identify and to understand highly reactive surfaces for solar hydrogen production. This project aims to develop advanced technology to produce hydrogen - carbon-free fuel - from water with sunlight as the only energy input. Using clean energy to replace fossil fuels can help address the issues of energy supply and reduce carbon emissions, which is critically important for a sustainable Australia.
Understanding and predicting small molecule binding to G protein-coupled receptors (GPCRs). The discovery of new treatments for serious diseases is a time consuming and expensive process. Our work involves developing and testing new computational modelling approaches with experimental validation for the understanding and prediction of how current and new drugs interact with their targets, and these methods can be extended for improved understanding of how other proteins work. Our approaches have ....Understanding and predicting small molecule binding to G protein-coupled receptors (GPCRs). The discovery of new treatments for serious diseases is a time consuming and expensive process. Our work involves developing and testing new computational modelling approaches with experimental validation for the understanding and prediction of how current and new drugs interact with their targets, and these methods can be extended for improved understanding of how other proteins work. Our approaches have the potential to increase the speed, reduce the cost and lead to the discovery of new treatments for serious crippling diseases such as anxiety, depression, diabetes, and obesity. Read moreRead less