Discovery Early Career Researcher Award - Grant ID: DE150100428
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Effect of natural seabed on hydrodynamics around cylindrical structures. This project aims to investigate the flow around a circular cylinder, placed near a plane boundary, as a fundamental fluid phenomenon and for applications of designing subsea pipelines. The proposed work will be carried out using a combined approach of physical model testing and numerical study. The effect of the plane boundary on flow transition from 2D to 3D, from sub-critical to critical turbulence regime will be examine ....Effect of natural seabed on hydrodynamics around cylindrical structures. This project aims to investigate the flow around a circular cylinder, placed near a plane boundary, as a fundamental fluid phenomenon and for applications of designing subsea pipelines. The proposed work will be carried out using a combined approach of physical model testing and numerical study. The effect of the plane boundary on flow transition from 2D to 3D, from sub-critical to critical turbulence regime will be examined. The project aims to derive a comprehensive set of force coefficients to predict hydrodynamic forces on pipelines that will improve the design of subsea pipelines. This project could provide significant benefits for the Australian subsea oil and gas industry.Read moreRead less
Crossing quantum-classical boundaries in a single particle. This project is aimed at constructing and observing an individual quantum system that can exhibit chaotic behaviour under controllable conditions. It is a long-sought goal of modern physics that can become reality for the first time in the world, thanks to the unique availability in Australia of the most quantum-coherent single spin ever made and a long history of theoretical advances in the field. Turning a spin into a chaotic system w ....Crossing quantum-classical boundaries in a single particle. This project is aimed at constructing and observing an individual quantum system that can exhibit chaotic behaviour under controllable conditions. It is a long-sought goal of modern physics that can become reality for the first time in the world, thanks to the unique availability in Australia of the most quantum-coherent single spin ever made and a long history of theoretical advances in the field. Turning a spin into a chaotic system will uncover the true nature of the quantum-classical boundary, and verify whether an underlying classical chaotic dynamics ultimately influences the behaviour of quantum systems. It is expected that the discoveries made will illuminate the path towards the technological exploitation of increasingly complex quantum devices.Read moreRead less