Developing the Helium Atom Pinhole Camera. The tantalising possibility of an optical instrument that uses neutral atom beams to image surfaces, rather than light or electrons, has been a grand challenge in Physics ever since de Broglie first postulated the existence of matter waves . This project seeks to realise this seminal goal using an elegantly simple design based on the concept of a pin hole camera. The successful development of this world-first instrument would represent a significant adv ....Developing the Helium Atom Pinhole Camera. The tantalising possibility of an optical instrument that uses neutral atom beams to image surfaces, rather than light or electrons, has been a grand challenge in Physics ever since de Broglie first postulated the existence of matter waves . This project seeks to realise this seminal goal using an elegantly simple design based on the concept of a pin hole camera. The successful development of this world-first instrument would represent a significant advance in helium atom microscopy and would significantly enhance the reputation of Australian science. Moreover, this project strengthens and supports a key collaboration between the Universities of Newcastle and Cambridge and is at the core of this emerging technology.Read moreRead less
Imaging with Neutral Atomic Beams: A Completely New Tool for Nanotechnology. The tantalising possibility of building an optical instrument that uses neutral atom beams to image surfaces, rather than light or electrons, has long been a goal of physical scientists across the world. This project aims to realise this goal using an elegantly simple design based on the concept of a pin hole camera. The successful development of this world-first instrument would represent a significant advance in heliu ....Imaging with Neutral Atomic Beams: A Completely New Tool for Nanotechnology. The tantalising possibility of building an optical instrument that uses neutral atom beams to image surfaces, rather than light or electrons, has long been a goal of physical scientists across the world. This project aims to realise this goal using an elegantly simple design based on the concept of a pin hole camera. The successful development of this world-first instrument would represent a significant advance in helium atom microscopy and would significantly enhance the reputation of Australian science. Moreover, this project maintains the position of Australian researchers and students at the core of this emerging technology.Read moreRead less
The Mechanics of Nanoscale Devices. Australian developments in biosensing, medical diagnostics, clean energy, communication and security technologies, are rapidly growing due to our mounting capacity in nanoscale fabrication. Vital for evolution of next-generation nanodevices is an understanding of how mechanical processes operate at such small scales. This application will contribute to this scientific knowledge base. This will in turn assist Australian industries to progress these applications ....The Mechanics of Nanoscale Devices. Australian developments in biosensing, medical diagnostics, clean energy, communication and security technologies, are rapidly growing due to our mounting capacity in nanoscale fabrication. Vital for evolution of next-generation nanodevices is an understanding of how mechanical processes operate at such small scales. This application will contribute to this scientific knowledge base. This will in turn assist Australian industries to progress these applications and devices, leading to economic, social and technological gains for the Australian community.Read moreRead less
Measurement of the spatial distribution of temperature and velocity in lakes using Acoustic Tomography. This project will investigate the use of acoustic tomography in lakes to continuously measure the lake-wide distribution of temperature and velocity. The challenges with lake acoustic tomography are the accuracy required in the travel time measurements over shorter distances, acoustic losses due to reflections and ensuring enough rays travel through the thermocline, the region of greatest inte ....Measurement of the spatial distribution of temperature and velocity in lakes using Acoustic Tomography. This project will investigate the use of acoustic tomography in lakes to continuously measure the lake-wide distribution of temperature and velocity. The challenges with lake acoustic tomography are the accuracy required in the travel time measurements over shorter distances, acoustic losses due to reflections and ensuring enough rays travel through the thermocline, the region of greatest interest in lakes. A pilot experiment in a deep lake will investigate the quality of travel time measurements computed from rays travelling through the thermocline of a strongly stratified lake. This has wide applications for the water quality management of lakes and reservoirs.Read moreRead less
Acoustic observation of Antarctic ice rifting and calving events using remote hydroacoustic listening stations. The calving activity of the Antarctic ice shelves is one of the major indicators of global climate change. Global warming induced by an increase in atmospheric CO2 will affect the Antarctic Ice Sheet, primarily in form of disintegration of the Antarctic ice shelves surrounding the continent. The processes of calving on the ice shelves may lead to a substantial increase of sea level aro ....Acoustic observation of Antarctic ice rifting and calving events using remote hydroacoustic listening stations. The calving activity of the Antarctic ice shelves is one of the major indicators of global climate change. Global warming induced by an increase in atmospheric CO2 will affect the Antarctic Ice Sheet, primarily in form of disintegration of the Antarctic ice shelves surrounding the continent. The processes of calving on the ice shelves may lead to a substantial increase of sea level around the world, with devastating effects on the continental coasts and low-lying islands. The method of remote acoustic observations investigated in this project is a new approach to the problem of creating an efficient and cost effective system to monitor rifting and calving of the Antarctic ice shelves. Read moreRead less
Spin-dependent interactions: a fundamental basis for spin-electronics. This project will establish a comprehensive understanding of spin-dependent interactions and correlated behaviour of multi-electron systems that are responsible for spin-relaxation, spin transport and spin coherence in spin-electronic devices. Our approach is based on the spin-resolved two-electron coincidence spectroscopy that is inherently suited for studying electronic correlations. Systematic investigations of spin-depend ....Spin-dependent interactions: a fundamental basis for spin-electronics. This project will establish a comprehensive understanding of spin-dependent interactions and correlated behaviour of multi-electron systems that are responsible for spin-relaxation, spin transport and spin coherence in spin-electronic devices. Our approach is based on the spin-resolved two-electron coincidence spectroscopy that is inherently suited for studying electronic correlations. Systematic investigations of spin-dependent interactions in atoms, molecules and ultrathin films will increase understanding of magnetic (spin) properties of artificially structured materials with reduced dimensionality for the benefit of nanotechnology. This understanding will be used to design and control, at the quantum mechanical level, the building blocks of spin-electronic devices.Read moreRead less
High-performance computational data-mining techniques for feature detection in complex time series from large-scale, networked plasma experiments. Terabytes of data are gathered from large experimental facilities as complex time-series. Analysis of these data is daunting, especially when they involve high-dimensional spectral or image arrays. We will develop high-performance computational techniques for dimension reduction, efficient data-mining, and experimental control, using as an initial ta ....High-performance computational data-mining techniques for feature detection in complex time series from large-scale, networked plasma experiments. Terabytes of data are gathered from large experimental facilities as complex time-series. Analysis of these data is daunting, especially when they involve high-dimensional spectral or image arrays. We will develop high-performance computational techniques for dimension reduction, efficient data-mining, and experimental control, using as an initial target the H-1NF plasma fusion MNRF at the ANU and its >100 GB/year data stream. The techniques will immediately provide Australian researchers with unique tools for collaboration in international research to develop fusion as a low-emissions source of electricity, and will be applicable to complex time-series analysis in other areas of science, medicine, and defence.Read moreRead less
Development of microwave tomography techniques and inverse methods for biomedical imaging applications. Microwave tomography is a rapidly emerging imaging technology with highly significant applications in industry and medicine. In particular, given its sensitivity to differences between normal and malignant breast tissue, non-invasive microwave imaging has been the subject of intense research interest in the last ten years. In collaboration with workers at Chalmers University in Sweden, we wi ....Development of microwave tomography techniques and inverse methods for biomedical imaging applications. Microwave tomography is a rapidly emerging imaging technology with highly significant applications in industry and medicine. In particular, given its sensitivity to differences between normal and malignant breast tissue, non-invasive microwave imaging has been the subject of intense research interest in the last ten years. In collaboration with workers at Chalmers University in Sweden, we will develop and evaluate a scanning microwave imaging tomographic system with a number of potential industrial and biomedical applications. This appears to be a new Australian initiative.Read moreRead less
Experimental Demonstrations of New Theorems of Nonequilibrium Thermodynamics. In the last decade, two theorems have been proposed to revolutionise the field of thermodynamics. These theorems lift the restriction of the thermodynamic limit, allowing thermodynamic concepts to be applied to small systems such as nanomachines, and characterise systems that may be far-from-equilibrium. These theorems are at odds with a traditional understanding of 19th century thermodynamics where equilibrium is cent ....Experimental Demonstrations of New Theorems of Nonequilibrium Thermodynamics. In the last decade, two theorems have been proposed to revolutionise the field of thermodynamics. These theorems lift the restriction of the thermodynamic limit, allowing thermodynamic concepts to be applied to small systems such as nanomachines, and characterise systems that may be far-from-equilibrium. These theorems are at odds with a traditional understanding of 19th century thermodynamics where equilibrium is central and the Second Law inviolate. However they are critical to the application of thermodynamic concepts to modern systems of the 21st century. Using Optical Tweezers, we will experimentally demonstrate these theorems, present irrefutable evidence of their validity, and demonstrate their application in modern systems.Read moreRead less
Decoherence in quantum computing and quantum electromechanical systems. Australia is one of the world leaders in fundamental studies and implementation of quantum computing and quantum electromechanical systems. By developing a framework to quantify and control noise due to decoherence in such systems, this research will facilitate progress in the development and understanding of quantum computing and quantum electromechanical devices. The project will also significantly strengthen the general r ....Decoherence in quantum computing and quantum electromechanical systems. Australia is one of the world leaders in fundamental studies and implementation of quantum computing and quantum electromechanical systems. By developing a framework to quantify and control noise due to decoherence in such systems, this research will facilitate progress in the development and understanding of quantum computing and quantum electromechanical devices. The project will also significantly strengthen the general representation of research on decoherence, a field of crucial importance to many areas of theoretical and experimental physics, in Australia. Funding of this project will enable Australia to further expand its leading position in cutting-edge science and next-generation technology.
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