The role of dopamine in the regulation of worker sterility in the honey bee. This project will open new doors into the knowledge of honey bees' sterility. We will not only show that certain genes control honey bee sterility but also that there is interactions between these genes and environmental cues such as the pheromones released by the queen. The project will provide significant material for a better understanding of honey bees society. Honey bees remain the most important pollinator world w ....The role of dopamine in the regulation of worker sterility in the honey bee. This project will open new doors into the knowledge of honey bees' sterility. We will not only show that certain genes control honey bee sterility but also that there is interactions between these genes and environmental cues such as the pheromones released by the queen. The project will provide significant material for a better understanding of honey bees society. Honey bees remain the most important pollinator world wide, and their conservation is a major concern both to agriculturalists and the general public. The project will be of immense scientific interest, and likely to be regarded as a major breakthrough. The project will also foster a strong intellectual collaboration between New Zealand and Australia.Read moreRead less
Enhancing natural convection heat transfer using a single horizontal non-metallic fin. This project will develop the basis for a simple design to improve the energy efficiency of natural convection heat exchangers. Heat exchangers are widely adopted in many electronic devices and industrial processes as they require no external power input, additional space, and are quiet, reliable and economical. The research will exploit the interaction between two flows to trigger turbulence, and will result ....Enhancing natural convection heat transfer using a single horizontal non-metallic fin. This project will develop the basis for a simple design to improve the energy efficiency of natural convection heat exchangers. Heat exchangers are widely adopted in many electronic devices and industrial processes as they require no external power input, additional space, and are quiet, reliable and economical. The research will exploit the interaction between two flows to trigger turbulence, and will result in an increase of the overall capacity and performance of engineering systems. This will contribute significantly to reductions in power consumption and improvements in productivity and work environment, leading ultimately to reductions in greenhouse gas emissions and to economic benefits.Read moreRead less
Investigation and optimisation of displacement ventilation and cooling systems. An accurate optimisation design tool for cooling and ventilation will be of considerable benefit to the Australian building/construction industry, and will lead to a reduction in energy consumption, thereby reducing both consumer costs and Australia's total greenhouse gas output, as well as providing Australian industry with a competitive advantage. Turbulence modelling for stratified fluids is one of the grand chall ....Investigation and optimisation of displacement ventilation and cooling systems. An accurate optimisation design tool for cooling and ventilation will be of considerable benefit to the Australian building/construction industry, and will lead to a reduction in energy consumption, thereby reducing both consumer costs and Australia's total greenhouse gas output, as well as providing Australian industry with a competitive advantage. Turbulence modelling for stratified fluids is one of the grand challenge areas of science, and graduate students and postdoctoral researchers trained in this area will be well placed to make a significant contribution to the new technologies needed to address the major environmental problems currently being faced.Read moreRead less
Turbulent fountains in stratified fluids with opposing buoyancy flux. Improved design tools will be developed for use in industries which must deal with turbulent fountains in stratified fluids. These tools will assist in the design of more efficient apparatus, reducing energy consumption and thereby reducing both consumer costs and Australia's total greenhouse gas output, as well as providing Australian industry with a competitive advantage. Turbulence modelling for stratified fluids is one of ....Turbulent fountains in stratified fluids with opposing buoyancy flux. Improved design tools will be developed for use in industries which must deal with turbulent fountains in stratified fluids. These tools will assist in the design of more efficient apparatus, reducing energy consumption and thereby reducing both consumer costs and Australia's total greenhouse gas output, as well as providing Australian industry with a competitive advantage. Turbulence modelling for stratified fluids is one of the grand challenge areas of science, and graduate students and postdoctoral researchers trained in this will provide continuing service to Australia in many areas of advanced engineering and science. Read moreRead less
An Investigation Into Fountains Interacting With Both Free Surface and Solid Boundaries. This project will produce an improved understanding of the behavior of fountains interacting with both free surface and solid boundaries. Such flows occur in many environmental and industrial processes and, in particular, the interaction of fountain with boundaries will have a significant influence on the overall performance of the processes. This investigation will combine experiments, numerical simulations ....An Investigation Into Fountains Interacting With Both Free Surface and Solid Boundaries. This project will produce an improved understanding of the behavior of fountains interacting with both free surface and solid boundaries. Such flows occur in many environmental and industrial processes and, in particular, the interaction of fountain with boundaries will have a significant influence on the overall performance of the processes. This investigation will combine experiments, numerical simulations and scaling analysis to provide new insight into the physics governing the behavior of these impinging fountains. Turbulence models will be developed and validated and scaling formulae will be obtained providing relationships for the basic flow properties in terms of the control parameters.Read moreRead less
Environmental stability of nanoscale materials for catalysis and sensing. After two decades of research, the first wave of 'nanotechnology' consumer products are entering the market, and large quantities of nanoparticles (less than millionth of a centimetre in size) are now being produced annually. However, before any new product can be manufactured, we need to know how stable engineered nanomaterials are before we bring them into our home, or we find them (unintentionally) free in our waterways ....Environmental stability of nanoscale materials for catalysis and sensing. After two decades of research, the first wave of 'nanotechnology' consumer products are entering the market, and large quantities of nanoparticles (less than millionth of a centimetre in size) are now being produced annually. However, before any new product can be manufactured, we need to know how stable engineered nanomaterials are before we bring them into our home, or we find them (unintentionally) free in our waterways and other ecosystems. For the first time, this project uses high performance supercomputing and advanced theoretical modelling to predict the stability of nanomaterials under a wide range of environmental conditions, to help safe guard Australia from potential 'nano-hazards' associated with these tiny pieces of matter.Read moreRead less
Investigating the coupled dependencies of soot in turbulent flames by advanced laser diagnostics and modelling. The community will benefit from the project by reduced air pollution and improved health and safety. Soot is a major air pollutant, adversely effecting public health, while also contributing directly to global warming. It also dominates heat transfer and influences the emissions of NOx and CO2. The project will significantly advance detailed understanding and modelling capability of fl ....Investigating the coupled dependencies of soot in turbulent flames by advanced laser diagnostics and modelling. The community will benefit from the project by reduced air pollution and improved health and safety. Soot is a major air pollutant, adversely effecting public health, while also contributing directly to global warming. It also dominates heat transfer and influences the emissions of NOx and CO2. The project will significantly advance detailed understanding and modelling capability of flames containing soot. Hence it will provide significantly improved capability to optimise these flames in applications spanning gas turbines, power generation, minerals processing and fires.Read moreRead less
Development of novel high efficiency thermoelectric oxides for high temperature power generation. Thermoelectric materials are considered as a key factor in clean energy production, based on the conversion of waste heat emitted by power plants and automobiles to electricity. A series of novel high performance Co-based oxide thermoelectric materials will be developed by this project using nanotechnology and advanced material processing techniques. Significant improvement of the heat-to-electricit ....Development of novel high efficiency thermoelectric oxides for high temperature power generation. Thermoelectric materials are considered as a key factor in clean energy production, based on the conversion of waste heat emitted by power plants and automobiles to electricity. A series of novel high performance Co-based oxide thermoelectric materials will be developed by this project using nanotechnology and advanced material processing techniques. Significant improvement of the heat-to-electricity conversion factor is expected to result from the proposed program. The novel thermoelectric oxides with high thermoelectric performance will be practically used for high temperature power generation. This will provide a long-term solution to the global warming threat through decreasing amounts of waste heat presently generated. Read moreRead less
Efficient and Robust Bi-directional Evolutionary Structural Optimisation Method for Large-scale Three-dimensional Topological Design. Structural optimisation is a process of searching for the best shape and topology of an engineering structure which will consume the least amount of material or energy. This project aims to further investigate the Bi-directional Structural Optimisation (BESO) method which has recently been proposed by the applicant's team. New algorithms will be developed to subst ....Efficient and Robust Bi-directional Evolutionary Structural Optimisation Method for Large-scale Three-dimensional Topological Design. Structural optimisation is a process of searching for the best shape and topology of an engineering structure which will consume the least amount of material or energy. This project aims to further investigate the Bi-directional Structural Optimisation (BESO) method which has recently been proposed by the applicant's team. New algorithms will be developed to substantially improve the efficiency and robustness of the BESO method. The expected outcome of the project is a simple and effective optimisation technique that can be used for the conceptual design of a wide range of engineering structures.Read moreRead less
Efficient Operation of Bioreactors using Nonlinear Dynamical Systems Theory. Current methods of determining optimal operating conditions in bioreactors have recently been shown to be inefficient, resulting in serious omissions of crucial parameter regions. We will use mathematical techniques from dynamical systems theory to establish a general framework by which bioreactor systems can be efficiently and systematically investigated to improve reactor performance. By communicating these results at ....Efficient Operation of Bioreactors using Nonlinear Dynamical Systems Theory. Current methods of determining optimal operating conditions in bioreactors have recently been shown to be inefficient, resulting in serious omissions of crucial parameter regions. We will use mathematical techniques from dynamical systems theory to establish a general framework by which bioreactor systems can be efficiently and systematically investigated to improve reactor performance. By communicating these results at relevant fora, we will increase the awareness within the Australian and international engineering communities of the advantages of modern mathematical techniques. Although this proposal focuses on bioreactors, the techniques can be easily adapted to improve the performances of other chemical processes.
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