Unravelling the mysteries of turbulent drag at the air-sea interface. 70% of the Earth's surface is the air-sea interface. A huge amount of energy and gas is exchanged between the atmosphere and ocean; exchanges that are crucial for life on earth. Climate models, weather and wave forecasts depend on oversimplified models for these exchanges. Oversimplification limits accuracy, with outcomes ranging from inaccurate climate predictions to costly and unnecessary rerouting of ships or evacuations of ....Unravelling the mysteries of turbulent drag at the air-sea interface. 70% of the Earth's surface is the air-sea interface. A huge amount of energy and gas is exchanged between the atmosphere and ocean; exchanges that are crucial for life on earth. Climate models, weather and wave forecasts depend on oversimplified models for these exchanges. Oversimplification limits accuracy, with outcomes ranging from inaccurate climate predictions to costly and unnecessary rerouting of ships or evacuations of oil platforms. This project promises new knowledge of the turbulent air flow above waves through innovative, ambitious experiments in our laboratory wind-wave tanks. Concurrently, novel numerical simulations will enable new models for sea drag coefficient, the most critical component in air-sea interaction models. Read moreRead less
Performance enhancement of tidal turbine arrays. Performance enhancement of tidal turbine arrays. This project aims to understand the environmental impact of turbines, by studying how an optimised array of turbines interacts with the downstream turbulent tidal flow. Tidal power could contribute substantially to Australia's Renewable Energy goals. Australia's coastlines produce over 2.4 terajoules of tidal energy, and research into turbine optimisation, array design and environmental impact is ne ....Performance enhancement of tidal turbine arrays. Performance enhancement of tidal turbine arrays. This project aims to understand the environmental impact of turbines, by studying how an optimised array of turbines interacts with the downstream turbulent tidal flow. Tidal power could contribute substantially to Australia's Renewable Energy goals. Australia's coastlines produce over 2.4 terajoules of tidal energy, and research into turbine optimisation, array design and environmental impact is needed to exploit this potential. Fluid dynamics and optimisation researchers will design an improved vertical axis tidal turbine for use in the Torres Strait Islands. This project could improve tidal turbine design and turbine placement designs, and improve understanding of interactions between turbines and the maritime environment.Read moreRead less
Aerodynamic interaction of bluff bodies with applications to sports aerodynamics. Numerical modelling and experiments will be combined by this project to characterise the flow and reduce drag on a set of objects in the wake of another object. The Olympic pursuit cycling team is a typical application, with small improvements leading to major competitiveness gains. Findings will also apply to Paralympic team sports, and potentially transportation.
Dissecting non-equilibrium effects in wall turbulence. This project aims to progress understanding of wall-bounded turbulent flows under non-equilibrium conditions. The focus is on turbulent flows over rough surfaces where the bulk flow decelerates along the streamwise length of the surface. Such flows are regularly encountered in important practical applications, such as over the trailing edge of an airplane wing or inside a flow diffuser, which are ubiquitous in industry. Novel experiments and ....Dissecting non-equilibrium effects in wall turbulence. This project aims to progress understanding of wall-bounded turbulent flows under non-equilibrium conditions. The focus is on turbulent flows over rough surfaces where the bulk flow decelerates along the streamwise length of the surface. Such flows are regularly encountered in important practical applications, such as over the trailing edge of an airplane wing or inside a flow diffuser, which are ubiquitous in industry. Novel experiments and numerical simulations will provide the definitive data needed in order to uncover the scaling laws of these flows, thus enabling their reliable prediction.Read moreRead less
Advanced Combustion Modelling for Scramjets and Rotating Detonation Engines. This project will develop new fundamental knowledge and engineering models underpinning air-breathing high speed propulsion engines employing complex hydrocarbon fuels. Extensive data and new physical understanding will be garnered through analysis of direct numerical simulations of supersonic reacting mixing layers including impinging shock waves. That data will be employed to isolate, test and develop computationally ....Advanced Combustion Modelling for Scramjets and Rotating Detonation Engines. This project will develop new fundamental knowledge and engineering models underpinning air-breathing high speed propulsion engines employing complex hydrocarbon fuels. Extensive data and new physical understanding will be garnered through analysis of direct numerical simulations of supersonic reacting mixing layers including impinging shock waves. That data will be employed to isolate, test and develop computationally efficient engineering models that are accurate and efficient for high speed combustion in rotating detonation engines and scramjets. Expected outcomes are knowledge and tools needed to develop practical and effective supersonic propulsion engines for access to space, defence and high speed point-to-point flight.
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Genesis and evolution of coherent structures in wall-bounded turbulence. This project aims to capture conditions responsible for the generation of the coherent structures that are formed in wall-bounded turbulent flows, through the use of variational data assimilation and adjoint-based optimisation techniques. The project is expected to provide knowledge and intellectual property that is essential for the accurate modelling and prediction of the interaction between the ground-level activities li ....Genesis and evolution of coherent structures in wall-bounded turbulence. This project aims to capture conditions responsible for the generation of the coherent structures that are formed in wall-bounded turbulent flows, through the use of variational data assimilation and adjoint-based optimisation techniques. The project is expected to provide knowledge and intellectual property that is essential for the accurate modelling and prediction of the interaction between the ground-level activities like pollutant emissions and the atmosphere and the flow over vehicles through pipes, turbines and compressors. This project will provide benefits such as reducing the risk in environmental and commercial design and decision making and will facilitate new opportunities for the commercial development of devices to reduce drag and enhance mixing and heat transfer via the direct manipulation of coherent structures.Read moreRead less
Understanding turbulent heat transfer with practical surface conditions. Heat transfer dictates the efficiency of energy and transport systems such as gas turbines, high-speed generators and turbochargers. These are among many applications where heat transfer involves turbulent fluid flow over solid surfaces, but where poor understanding of surface conditions leads to dubious models, suboptimal designs and cost penalties. This project therefore aims to advance our fundamental understanding of he ....Understanding turbulent heat transfer with practical surface conditions. Heat transfer dictates the efficiency of energy and transport systems such as gas turbines, high-speed generators and turbochargers. These are among many applications where heat transfer involves turbulent fluid flow over solid surfaces, but where poor understanding of surface conditions leads to dubious models, suboptimal designs and cost penalties. This project therefore aims to advance our fundamental understanding of heat transfer accounting for the practical surface conditions of roughness, solid-fluid pairing and uneven heating. Building on capabilities that now place systematic data within reach, this project will deliver physics-based models that can robustly predict heat transfer, leading to reduced costs of energy and transport.Read moreRead less
Tailoring aircraft surface textures to minimise drag. This project aims to optimise textured surfaces for reducing fluid dynamic drag. The project builds on recent breakthroughs in drag-evaluation methods and the associated physics. Reducing drag is valuable because it raises the costs of operating aircraft and ships. The intended outcomes are optimal drag-reducing surface textures, a further physical understanding of drag-reduction mechanisms and an improved modelling capability of drag-reducin ....Tailoring aircraft surface textures to minimise drag. This project aims to optimise textured surfaces for reducing fluid dynamic drag. The project builds on recent breakthroughs in drag-evaluation methods and the associated physics. Reducing drag is valuable because it raises the costs of operating aircraft and ships. The intended outcomes are optimal drag-reducing surface textures, a further physical understanding of drag-reduction mechanisms and an improved modelling capability of drag-reducing surfaces. This project is expected to benefit the transport and logistics industries in Australia and globally.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101396
Funder
Australian Research Council
Funding Amount
$421,209.00
Summary
Dynamics and dispersion of microplastics in turbulent shallow water flows. Microplastics have become ubiquitous in our rivers, lakes and reservoirs, detrimentally impacting ecosystems. Via high-fidelity numerical simulations, the project aims to advance our understanding of the complex interplay between dispersed microplastics and key fluvial processes including turbulence, sediment transport and free-surface wave dynamics. The project intends to buildup a data-base containing high-resolution da ....Dynamics and dispersion of microplastics in turbulent shallow water flows. Microplastics have become ubiquitous in our rivers, lakes and reservoirs, detrimentally impacting ecosystems. Via high-fidelity numerical simulations, the project aims to advance our understanding of the complex interplay between dispersed microplastics and key fluvial processes including turbulence, sediment transport and free-surface wave dynamics. The project intends to buildup a data-base containing high-resolution data of the occurrence, trajectories and distribution of microplastics. The outcome is anticipated to be invaluable in improving microplastic transport models, standardisation of sampling and quantification techniques, and in designing innovative mitigation technologies for microplastic collection.
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From trip to tail: tracking the origins, development and evolution of coherent structures in turbulent boundary layers. This project will investigate the lifespan of large-scale repeating patterns within turbulent boundary layers (the thin layer of chaotic fluid that envelopes a body as it moves through a fluid). These recurrent patterns play an important role in our lives, dictating the drag of aircraft and dominating environmental processes in the lower atmosphere.