Electron Emission from Diamond. Israel is emerging as an international hub of technology with one of the highest rates of R&D in the world. This collaborative project will access one of the world leading experts in diamond science and technology, Professor Alon Hoffman, to exploit the remarkable properties of diamond for a new generation of detectors and devices. Success in this project can lay the groundwork for tapping into the successful record of advanced technologies and venture capital fun ....Electron Emission from Diamond. Israel is emerging as an international hub of technology with one of the highest rates of R&D in the world. This collaborative project will access one of the world leading experts in diamond science and technology, Professor Alon Hoffman, to exploit the remarkable properties of diamond for a new generation of detectors and devices. Success in this project can lay the groundwork for tapping into the successful record of advanced technologies and venture capital funding that abound in Israel today. Read moreRead less
High-energy electron scattering of surfaces: new spectroscopies and new physics. Electrons sometimes behave as particles, and sometimes as waves. Both aspects are used when investigating nano-structures with electron beams. In this research program we design and perform experiments to measure sample composition using the particle nature, and the atom positions by using the wave nature of electrons. These novel experiments, using unique spectrometers designed and developed in Australia, are aime ....High-energy electron scattering of surfaces: new spectroscopies and new physics. Electrons sometimes behave as particles, and sometimes as waves. Both aspects are used when investigating nano-structures with electron beams. In this research program we design and perform experiments to measure sample composition using the particle nature, and the atom positions by using the wave nature of electrons. These novel experiments, using unique spectrometers designed and developed in Australia, are aimed at making new forms of electron microscopy possible, but will also result in a better understanding of existing electron microscopies and synchrotron-based measurements.Read moreRead less
Foundation studies of ion-beam nanotechnology. The impact of a single fast atom with sensitive materials leaves a path of latent damage with a diameter of around 10 nm. This latent damage can be developed to create nanostructures in a novel technique called ion beam nanomachining. We propose to create a method for using single atom impacts to produce nanomachined structures with novel physical and optical properties. This will be done by use of an active substrate that functions as a detector s ....Foundation studies of ion-beam nanotechnology. The impact of a single fast atom with sensitive materials leaves a path of latent damage with a diameter of around 10 nm. This latent damage can be developed to create nanostructures in a novel technique called ion beam nanomachining. We propose to create a method for using single atom impacts to produce nanomachined structures with novel physical and optical properties. This will be done by use of an active substrate that functions as a detector sensitive to single ion impacts. We propose to study the fundamental principles of this method.Read moreRead less
Photoemission studies of Fermi surfaces, of wide bandgap semi-conductors and quasi crystals. Knowledge of the detailed shape of the Fermi surface of a conducting material is vital for an understanding of its electrical and magnetic properties. We will use angle resolved photo-emission in conjunction with synchrotron radiation to explore the Fermi surfaces of technologically important magnetic alloys, the mechanism driving the occurance of charge density waaves in layer compounds and the electron ....Photoemission studies of Fermi surfaces, of wide bandgap semi-conductors and quasi crystals. Knowledge of the detailed shape of the Fermi surface of a conducting material is vital for an understanding of its electrical and magnetic properties. We will use angle resolved photo-emission in conjunction with synchrotron radiation to explore the Fermi surfaces of technologically important magnetic alloys, the mechanism driving the occurance of charge density waaves in layer compounds and the electronic properties of wide band-gap semi-conductors such as GaN, SiC and of selected quasi crystals. These measurements will be performed using a unique high resolution toroidal spectrometer currently under construction at La Trobe university.Read moreRead less
Optical Information Processing with Diamond. The explosive growth in ideas for applications of quantum mechanics to practical devices for information processing has been a worldwide phenomenon of the past 4 years. A leading material which promises many of the desirable quantum properties is diamond. We aim to build on our extensive expertise in fundamental diamond research to design, fabricate and analyse novel quantum devices made from diamond. We will seek to attain the glittering prize of ....Optical Information Processing with Diamond. The explosive growth in ideas for applications of quantum mechanics to practical devices for information processing has been a worldwide phenomenon of the past 4 years. A leading material which promises many of the desirable quantum properties is diamond. We aim to build on our extensive expertise in fundamental diamond research to design, fabricate and analyse novel quantum devices made from diamond. We will seek to attain the glittering prize of constructing diamond devices that will absorb, store and re-emit single light-photons with revolutionary applications to information storage and processing.Read moreRead less
Fabrication strategies for diamond-based quantum devices: concepts to applications. Twenty first technology must respond to the imperatives of low-power, high speed, and integrated functionality. The application of our most advanced scientific understanding is required to meet these imperatives: quantum physics. Quantum information Science is radically altering our understanding of physics, and is ripe to change engineering and technology. One of the most promising material platforms for explo ....Fabrication strategies for diamond-based quantum devices: concepts to applications. Twenty first technology must respond to the imperatives of low-power, high speed, and integrated functionality. The application of our most advanced scientific understanding is required to meet these imperatives: quantum physics. Quantum information Science is radically altering our understanding of physics, and is ripe to change engineering and technology. One of the most promising material platforms for exploiting quantum effects is diamond, and our project seeks to transition diamond from its role as scientific testbed, to the material of choice for quantum technologiesRead moreRead less
Visualizing spin-related properties of functional nanostructures (for spintronics). This project contributes to undergraduate, postgraduate and postdoctoral research and training to encourage the pursuit of excellence, with:
- increased depth of knowledge in interdisciplinary research,
- a scientific environment providing access to research not otherwise in Australia,
- experience in the design, construction and development of scientific instruments.
Possible applications include high-speed ....Visualizing spin-related properties of functional nanostructures (for spintronics). This project contributes to undergraduate, postgraduate and postdoctoral research and training to encourage the pursuit of excellence, with:
- increased depth of knowledge in interdisciplinary research,
- a scientific environment providing access to research not otherwise in Australia,
- experience in the design, construction and development of scientific instruments.
Possible applications include high-speed magnetic filters, sensors, quantum transistors and spin qubits for quantum computers. The technological aspects of our project's outcomes offer real prospects of local development. The development of spin-polarized electron spectroscopy has great potential for existing applications in the surface science industry.
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Many-Electron Dynamics and Electronic Structure of Materials Studied by Electron Momentum Spectroscopy. Electron momentum spectroscopy is a technique that resembles playing pool with electrons. This technique, largely developed in Australia, determines the binding energy and velocity distribution of electrons in matter. This distribution, closely related to the quantum mechanical wave function of the electrons, can be compared directly with calculations of the electronic structure. Such a compa ....Many-Electron Dynamics and Electronic Structure of Materials Studied by Electron Momentum Spectroscopy. Electron momentum spectroscopy is a technique that resembles playing pool with electrons. This technique, largely developed in Australia, determines the binding energy and velocity distribution of electrons in matter. This distribution, closely related to the quantum mechanical wave function of the electrons, can be compared directly with calculations of the electronic structure. Such a comparison helps establish which theory approaches nature most closely, and thus improves our understanding of the electronic structure. This understanding helps to predict the properties of materials, and hence this knowledge will facilitate the design of materials with desirable properties.Read moreRead less
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