Nanocomposite Mesoporous Materials for Gas Separations of Environmental Significance. The management of greenhouse and other acid gas emissions is vital to a sustainable future of both the economy and the ecosystem. This project will develop novel nano-materials for gas separation by tethering organic functional groups to the surface of porous inorganic supports. These materials offer the promise of combining the high selectivity and high capacity of liquid phase absorption systems with the rapi ....Nanocomposite Mesoporous Materials for Gas Separations of Environmental Significance. The management of greenhouse and other acid gas emissions is vital to a sustainable future of both the economy and the ecosystem. This project will develop novel nano-materials for gas separation by tethering organic functional groups to the surface of porous inorganic supports. These materials offer the promise of combining the high selectivity and high capacity of liquid phase absorption systems with the rapid transport rates of gas-solid adsorption systems. Success would open up several new possibilities for reengineering gas separation systems based on the use of these materials in solution, as solid phase adsorbents (pressure swing adsorption) and/or as permeselective gas membranes.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668477
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
Upgrade of existing university low field and high field nuclear magnetic resonance facilities. The ongoing pursuit of new medicines and therapies, the development of sustainable forestry management practices and the assessment of the impact of global climate change on Australian forest soils are some of the research objectives being addressed by researchers at Griffith University. The Eskitis Institute for Cell and Molecular Therapies and the Centre for Forestry and Horticultural Research (CFHR) ....Upgrade of existing university low field and high field nuclear magnetic resonance facilities. The ongoing pursuit of new medicines and therapies, the development of sustainable forestry management practices and the assessment of the impact of global climate change on Australian forest soils are some of the research objectives being addressed by researchers at Griffith University. The Eskitis Institute for Cell and Molecular Therapies and the Centre for Forestry and Horticultural Research (CFHR) bring together researchers from a range of disciplines to further research in these key areas. The instruments funded here will provide researchers with access to spectroscopic facilities with state-of-the-art performance. This will ensure the continued international competitiveness and the sustained productivity of our research programmes.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150100427
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
All-in-one Functional Nanocrystal Inks for Printed Inorganic Solar Cells. At present, manufacturing solar panels involves expensive high temperature and high vacuum processes. The bottleneck to cheaper solar power is the ability to design new methods of manufacturing. The ability to print the active components of a solar cell is an excellent way to mitigate these costs. This project aims to focus on developing the knowledge to print the most crucial component of a solar cell - the light absorbin ....All-in-one Functional Nanocrystal Inks for Printed Inorganic Solar Cells. At present, manufacturing solar panels involves expensive high temperature and high vacuum processes. The bottleneck to cheaper solar power is the ability to design new methods of manufacturing. The ability to print the active components of a solar cell is an excellent way to mitigate these costs. This project aims to focus on developing the knowledge to print the most crucial component of a solar cell - the light absorbing layer. Innovative nanoscience will be used to develop novel solar inks composed of tiny semiconductor crystals. The formulation and transformation of these inks into efficient semiconductor light absorbing layers, with a clear view to cheaper printed solar cells, will be the key objective of this project.Read moreRead less
Deep ocean thermodynamics and climate change. This project aims to obtain new insights into the thermodynamic and transport properties of mixtures containing water, particularly at high pressures, that impact directly on our understanding of climate change processes. The project will involve the use of a polarisable potential for water which has recently been demonstrated to yield predictions of high accuracy. It will be used to model saline water mixtures containing carbon dioxide, resulting in ....Deep ocean thermodynamics and climate change. This project aims to obtain new insights into the thermodynamic and transport properties of mixtures containing water, particularly at high pressures, that impact directly on our understanding of climate change processes. The project will involve the use of a polarisable potential for water which has recently been demonstrated to yield predictions of high accuracy. It will be used to model saline water mixtures containing carbon dioxide, resulting in valuable data for thermodynamic properties of the world's oceans. These data are of crucial importance for accurate climate change predictions and as such the project will have an important impact on understanding our changing environment.Read moreRead less
The charXive challenge and the clean coal quest: thermokinetic principles and methods for capturing and sequestering carbon dioxide. Article 6 of the Kyoto Protocol, which Australia signed in 2007, states that a transfer of carbon credits may only take place if the associated activity provides a reduction in emissions by sources or an enhancement of removals by sinks that is additional to any that would otherwise occur. Since biochar production reduces emissions from biomass decay and transfers ....The charXive challenge and the clean coal quest: thermokinetic principles and methods for capturing and sequestering carbon dioxide. Article 6 of the Kyoto Protocol, which Australia signed in 2007, states that a transfer of carbon credits may only take place if the associated activity provides a reduction in emissions by sources or an enhancement of removals by sinks that is additional to any that would otherwise occur. Since biochar production reduces emissions from biomass decay and transfers oxidized carbon from the atmosphere to the inactive black carbon pool this project will contribute to the national effort in additional greenhouse gas abatements. The Australian Government is also committed to clean coal technologies, which are expensive. An economically viable method of capturing carbon emissions from electricity generators will result from this project.Read moreRead less
Novel Nanomaterials for Photocatalytic Water Purification - Science and Application. Water is rapidly becoming Australia's most critical natural resource, and there is an urgent need to re-use and recycle water from domestic use (graywater) and industry, as well as utilisation of larger scale harvesting of rainwater. The outcome of this project will be a technology which can remove organic material (biological and non-biological) from water, enabling a greater range of uses of wastewater. This ....Novel Nanomaterials for Photocatalytic Water Purification - Science and Application. Water is rapidly becoming Australia's most critical natural resource, and there is an urgent need to re-use and recycle water from domestic use (graywater) and industry, as well as utilisation of larger scale harvesting of rainwater. The outcome of this project will be a technology which can remove organic material (biological and non-biological) from water, enabling a greater range of uses of wastewater. This technology will play a significant role in delivering future water security, and developing new industries involved in manufacture and export of water treatment technologies. This project directly addresses the National Priority Research area of water, and international priorities involving greater re-use and recycling of water.Read moreRead less
Reduced water usage in the Australian pulp and paper industry through novel process chemistry. Norske Skog Paper Mill operates two paper mills on major rivers in Australia. For these mills to reduce water consumption greater recycling of the process water is needed which results in a build-up of detrimental substances that will affect paper machine performance and efficiency. The knowledge gained from this project will help the paper mills to find strategies to control the build-up of the detr ....Reduced water usage in the Australian pulp and paper industry through novel process chemistry. Norske Skog Paper Mill operates two paper mills on major rivers in Australia. For these mills to reduce water consumption greater recycling of the process water is needed which results in a build-up of detrimental substances that will affect paper machine performance and efficiency. The knowledge gained from this project will help the paper mills to find strategies to control the build-up of the detrimental material and deal with it in such a way that the process water can be recycled and the paper mills can reduce water consumption.Read moreRead less
Development of a novel biodegradable ophthalmic biomaterial based on porous silicon. Within this interdisciplinary project, we will combine our diverse expertise towards the development of frontier technologies for control of stem cell behaviour on biodegradable scaffold materials. We will develop a novel ophthalmic bioimplant from porous silicon using topographical and chemical aspects of surface modification as well as immobilisation and/or incorporation of bioactive species such as growth fac ....Development of a novel biodegradable ophthalmic biomaterial based on porous silicon. Within this interdisciplinary project, we will combine our diverse expertise towards the development of frontier technologies for control of stem cell behaviour on biodegradable scaffold materials. We will develop a novel ophthalmic bioimplant from porous silicon using topographical and chemical aspects of surface modification as well as immobilisation and/or incorporation of bioactive species such as growth factors, to permit the growth and differentiation of mammalian stem cells. This project will result in biomaterials for the treatment of blinding diseases of the eye. Implanted into the limbus, bioimplants may ameliorate some common corneal diseases.Read moreRead less
The role of fat crystal wettability in altering dairy emulsion properties. The role of fat crystal wettability in altering dairy emulsion properties. This project aims to control fat crystal wettability, to create tailored dairy products with desirable stability, shelf-life and texture. Fat crystals are an essential component of dairy emulsions (fat droplets dispersed in dairy/milk serum) and control product processing, shelf life and texture. Their structuring role involves partial coalescence: ....The role of fat crystal wettability in altering dairy emulsion properties. The role of fat crystal wettability in altering dairy emulsion properties. This project aims to control fat crystal wettability, to create tailored dairy products with desirable stability, shelf-life and texture. Fat crystals are an essential component of dairy emulsions (fat droplets dispersed in dairy/milk serum) and control product processing, shelf life and texture. Their structuring role involves partial coalescence: the formation of complicated network structures of fat droplets. Unless fat crystals are partially wetted by water, they will not be present at the fat droplet interface, and partial coalescence will not occur. Expected outcomes are new dairy products with optimum stability and texture.Read moreRead less
Study of molecular interactions between wood pitch fixatives and components of wood pitch. Wood resins, released in pulping, agglomerate in the papermaking process to cause pitch deposits. These deposits adversely affect paper machine efficiency and product quality and limit further recycling of process water. This project aims to investigate the interactions between the components of the wood resins and different fixatives using capillary electrophoresis and other techniques. This knowledge w ....Study of molecular interactions between wood pitch fixatives and components of wood pitch. Wood resins, released in pulping, agglomerate in the papermaking process to cause pitch deposits. These deposits adversely affect paper machine efficiency and product quality and limit further recycling of process water. This project aims to investigate the interactions between the components of the wood resins and different fixatives using capillary electrophoresis and other techniques. This knowledge will provide a better understanding of the role of the physical and chemical properties of the fixatives in fixing the different compounds in wood resins. Molecular modelling will be used to design new fixatives that will be selective to a mixture of wood resins.
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