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Reducing rocket resonance is the key to safer spaceflight. This fellowship considers a particularly dangerous component of rocket launch, which is the potential for destructive feedback loops to form either in the nozzle, or between the nozzle and the launch pad. CI Edgington-Mitchell is a world leader in the study of resonance in jet engines, having developed best-in-field methodologies for the problem. In this innovative fellowship, he will apply these methodologies to better understand the da ....Reducing rocket resonance is the key to safer spaceflight. This fellowship considers a particularly dangerous component of rocket launch, which is the potential for destructive feedback loops to form either in the nozzle, or between the nozzle and the launch pad. CI Edgington-Mitchell is a world leader in the study of resonance in jet engines, having developed best-in-field methodologies for the problem. In this innovative fellowship, he will apply these methodologies to better understand the dangerous resonances that can occur during rocket launch, using a combination of experimental, numerical, and theoretical techniques, in partnership with NASA, Stanford, and the CNRS.Read moreRead less
Impact of roughness on adverse pressure gradient turbulent boundary layers. This project aims to develop a novel technique for measuring time-resolved fluid velocity vector fields in high-speed flows to investigate rough wall turbulence in adverse pressure gradient environments in unprecedented detail. By using this innovative instrument to study these widespread but poorly understood turbulent flows in power generation and transport, the project seeks to generate new knowledge. Expected outcome ....Impact of roughness on adverse pressure gradient turbulent boundary layers. This project aims to develop a novel technique for measuring time-resolved fluid velocity vector fields in high-speed flows to investigate rough wall turbulence in adverse pressure gradient environments in unprecedented detail. By using this innovative instrument to study these widespread but poorly understood turbulent flows in power generation and transport, the project seeks to generate new knowledge. Expected outcomes include the development of a new instrument and fundamental knowledge leading to improved designs with higher efficiencies in power generation and transport, resulting in significant benefits such as increased energy security, reduced greenhouse gas emissions, and improved quality of life for individuals and society.Read moreRead less
Microfluidics to explore the uptake of nanoparticles by endothelial cells. This project aims to develop microfluidic technologies for generating lipid nanoparticles with customised properties and investigating their delivery to endothelial cells under various flow dynamics. The project expects to advance our fundamental knowledge of biophysical and biological mechanisms underlying the uptake of lipid nanoparticles by endothelial cells. Expected outcomes of this project include enhanced delivery ....Microfluidics to explore the uptake of nanoparticles by endothelial cells. This project aims to develop microfluidic technologies for generating lipid nanoparticles with customised properties and investigating their delivery to endothelial cells under various flow dynamics. The project expects to advance our fundamental knowledge of biophysical and biological mechanisms underlying the uptake of lipid nanoparticles by endothelial cells. Expected outcomes of this project include enhanced delivery of nanoparticles to vessel walls. This should provide significant benefits, such as establishing a framework for designing future nano delivery systems, which would benefit Australian biotechnology industries.
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Scaling laws for aerodynamics of moving wings in the Martian atmosphere. This project aims to increase understanding of the aerodynamics of bio-inspired flight in the low-density atmosphere of Mars. The significance of flight in planetary exploration is shown by the ongoing success of the Ingenuity helicopter on Mars, and the Dragonfly rotorcraft planned for use on Titan. Expected outcomes of this project will be innovative numerical modelling techniques validated using local specially designed ....Scaling laws for aerodynamics of moving wings in the Martian atmosphere. This project aims to increase understanding of the aerodynamics of bio-inspired flight in the low-density atmosphere of Mars. The significance of flight in planetary exploration is shown by the ongoing success of the Ingenuity helicopter on Mars, and the Dragonfly rotorcraft planned for use on Titan. Expected outcomes of this project will be innovative numerical modelling techniques validated using local specially designed low-pressure experimental facilities. Benefits will be more accurate design guidance for efficient and robust flapping and rotary wing robotic vehicles for Mars and other space exploration that take advantage of the unique atmospheric conditions, and in placing Australia at the forefront of such design technology.Read moreRead less
An adaptive surface for improved modelling of rough wall bounded turbulence. This project aims to improve the prediction of drag where fluid flows over rough surfaces. This is a significant problem, with the uncertainty in drag penalty prediction for shipping alone exceeding ten billion dollars annually. The societal importance of these flows demands action, yet novel approaches must be sought to efficiently explore the wide range of roughness types encountered in practice. An adaptive surface i ....An adaptive surface for improved modelling of rough wall bounded turbulence. This project aims to improve the prediction of drag where fluid flows over rough surfaces. This is a significant problem, with the uncertainty in drag penalty prediction for shipping alone exceeding ten billion dollars annually. The societal importance of these flows demands action, yet novel approaches must be sought to efficiently explore the wide range of roughness types encountered in practice. An adaptive surface is proposed, where a roughness configuration can be dialled in at the press of a button, to rapidly converge on improved models. A key outcome of this project will be improved predictive models of drag for rough wall flows. Benefits will include improved efficiencies and reduced emissions across a wide range of industries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100754
Funder
Australian Research Council
Funding Amount
$426,154.00
Summary
Drag Prediction over Rough Surfaces using Hardware-Accelerated Simulations. This project aims to uncover the relationship between roughness topography and drag by utilising high-performance and efficient hardware acceleration. This project expects to generate new knowledge in the area of rough-wall turbulent boundary layer by using state-of-the-art hardware accelerated high fidelity simulations and machine learning techniques to identify important roughness parameters. Expected outcomes of this ....Drag Prediction over Rough Surfaces using Hardware-Accelerated Simulations. This project aims to uncover the relationship between roughness topography and drag by utilising high-performance and efficient hardware acceleration. This project expects to generate new knowledge in the area of rough-wall turbulent boundary layer by using state-of-the-art hardware accelerated high fidelity simulations and machine learning techniques to identify important roughness parameters. Expected outcomes of this project include the development of a novel, more accurate, and robust model to predict drag. This would lead to improved data-driven policies for more sustainable and profitable airline and maritime industries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100131
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Multifunctional micro/nano-engineered solar thermal receivers. This project is designed to develop a new class of thermal receivers that overcome key challenges in today's concentrating solar thermal systems. The development of accurate micro/nanofabrication and characterisation techniques in recent years has made it possible to achieve thermofluid devices that are engineered from the bottom up to achieve high performance at relatively low cost. This project aims to develop a new class of solar ....Multifunctional micro/nano-engineered solar thermal receivers. This project is designed to develop a new class of thermal receivers that overcome key challenges in today's concentrating solar thermal systems. The development of accurate micro/nanofabrication and characterisation techniques in recent years has made it possible to achieve thermofluid devices that are engineered from the bottom up to achieve high performance at relatively low cost. This project aims to develop a new class of solar thermal receivers which use micro/nanotechnology to directly absorb concentrated solar energy with very little pumping power and minimal radiative heat loss. By tailoring the geometry and materials inside the receiver, the project expects to achieve a unique level of integrated optical, heat transfer and fluid flow control.Read moreRead less
Novel framework for optimising battery-cooling microchannel heat exchangers. Thermal overheating can affect the capacity, safety and life expectancy of batteries for renewable energy storage and electric vehicles. Microscale heat exchangers are a potential high-efficiency, low-bulk solution. This project aims to develop a novel computational methodology to optimise the design of those heat exchangers in which viscoelastic fluids are used to control flow instabilities and enhance heat transfer at ....Novel framework for optimising battery-cooling microchannel heat exchangers. Thermal overheating can affect the capacity, safety and life expectancy of batteries for renewable energy storage and electric vehicles. Microscale heat exchangers are a potential high-efficiency, low-bulk solution. This project aims to develop a novel computational methodology to optimise the design of those heat exchangers in which viscoelastic fluids are used to control flow instabilities and enhance heat transfer at the microscale. A new microscopic fluid physics model will provide data for an innovative neural network framework to optimise the working fluid conditions and microscale design, which could contribute to increased adoption of renewable energy technologies that are supported by microscale heat exchangers.Read moreRead less
On the Hunt: Boosting Productivity of Cell Factories by Advanced Searches . This project aims to advance our fundamental understanding of molecular mechanisms underlying protein secretion in yeast, an industrial workhorse and a model organism. It will develop a unique multifaceted research platform to identify and analyse superior yeast strains with the desired traits at the single-cell level. Expected outcomes include a new analytical tool for high-throughput strain analysis and advanced knowle ....On the Hunt: Boosting Productivity of Cell Factories by Advanced Searches . This project aims to advance our fundamental understanding of molecular mechanisms underlying protein secretion in yeast, an industrial workhorse and a model organism. It will develop a unique multifaceted research platform to identify and analyse superior yeast strains with the desired traits at the single-cell level. Expected outcomes include a new analytical tool for high-throughput strain analysis and advanced knowledge of yeast molecular biology that can be applied to improve cell factories for the next generation of fuels, food and pharmaceuticals. This will provide significant economic and social benefits by boosting biotech industry growth, facilitating the transition to a sustainable society and improving Australia’s biosecurity.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100400
Funder
Australian Research Council
Funding Amount
$425,963.00
Summary
Fallopian tube on-a-chip for understanding mammalian reproduction. This project aims to reveal the fundamental physics and biology of mammalian reproduction by engineering the first comprehensive 3D culture model of the fallopian tube. The project expects to generate significant new knowledge about the exact role of the fallopian tube anatomy and physiology on the formation and function of epithelial tissue, using innovative approaches to simultaneously measure the full dynamics of epithelial ce ....Fallopian tube on-a-chip for understanding mammalian reproduction. This project aims to reveal the fundamental physics and biology of mammalian reproduction by engineering the first comprehensive 3D culture model of the fallopian tube. The project expects to generate significant new knowledge about the exact role of the fallopian tube anatomy and physiology on the formation and function of epithelial tissue, using innovative approaches to simultaneously measure the full dynamics of epithelial cell activity and sperm motion. The expected outcome of the project is to reveal the cooperative role of sperm, egg and epithelial tissue on fertilisation. This should provide significant benefits, such as important biophysical insights into mammalian reproduction and new research tools to replace animal models.Read moreRead less