Discovery Early Career Researcher Award - Grant ID: DE130100739
Funder
Australian Research Council
Funding Amount
$354,958.00
Summary
Deterministic coherent diffractive imaging for the nanosciences. The technological trend towards nanoscale device fabrication demands picoscale measurements which will only be possible with the development of novel and advanced imaging techniques. This project will develop and implement cutting edge approaches to lensless imaging using both electrons and x-rays and will enable real-time imaging at the picoscale.
Unlocking the potential of magnetic 2D materials with quantum microscopy. This project aims to create a universal, high-throughput platform to characterise magnetic 2D materials, by exploiting recently developed quantum diamond microscopy. It will enable the measurement of hitherto inaccessible magnetic properties of individual 2D microsheets, the imaging of device-relevant phenomena such as domain wall dynamics and skyrmionics, and the systematic screening of newly synthesised materials. Antici ....Unlocking the potential of magnetic 2D materials with quantum microscopy. This project aims to create a universal, high-throughput platform to characterise magnetic 2D materials, by exploiting recently developed quantum diamond microscopy. It will enable the measurement of hitherto inaccessible magnetic properties of individual 2D microsheets, the imaging of device-relevant phenomena such as domain wall dynamics and skyrmionics, and the systematic screening of newly synthesised materials. Anticipated outcomes include crucial new insights into 2D magnetism and the discovery of magnetic 2D materials compatible with real-world conditions. This should accelerate the development of future energy-efficient and flexible electronics and memory technologies, where magnetic 2D materials are expected to play a key role.
Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100129
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Two-dimensional spintronics probed with diamond quantum sensors. This project aims to understand the spintronic properties of graphene. Graphene, a ground-breaking two-dimensional material, has tremendous potential for the realisation of high-speed, low-power operation, spin-logic devices for next-generation electronics. However, for its full potential to be reached, techniques are needed to directly probe and image spins in operating devices. The project plans to exploit recently developed diam ....Two-dimensional spintronics probed with diamond quantum sensors. This project aims to understand the spintronic properties of graphene. Graphene, a ground-breaking two-dimensional material, has tremendous potential for the realisation of high-speed, low-power operation, spin-logic devices for next-generation electronics. However, for its full potential to be reached, techniques are needed to directly probe and image spins in operating devices. The project plans to exploit recently developed diamond quantum sensing technologies to characterise graphene spintronic devices. The results and methods are expected to clarify the underlying microscopic mechanisms and provide a route to design and optimise functional graphene spintronic devices.Read moreRead less
Single spin molecular microscope. This project aims to create a new tool for imaging and analysing material at the atomic level. The tool is based on individual quantum coherent spins in diamond which can be manipulated and optically read. The project expects to generate knowledge in quantum metrology and an understanding of molecular dynamics at the nanoscale. The expected outcome is a new type of device capable of imaging complex physical systems at the level of their individual constituent co ....Single spin molecular microscope. This project aims to create a new tool for imaging and analysing material at the atomic level. The tool is based on individual quantum coherent spins in diamond which can be manipulated and optically read. The project expects to generate knowledge in quantum metrology and an understanding of molecular dynamics at the nanoscale. The expected outcome is a new type of device capable of imaging complex physical systems at the level of their individual constituent components. This has significant benefits in improving designer materials, energy production, information storage, and drug design.Read moreRead less
Designing and controlling superconducting circuits for quantum information processing. Superconducting circuits are the quantum version of the standard electric circuits and, as the electric circuit did for the electronics industry, they promise a revolution for quantum technologies. This project aims to design superconducting circuits that are more robust to noise and useful for quantum information processing.
Nanoscale field mapping in functional materials. This project aims to develop tools to map electric and magnetic fields within matter on smaller-length scales than has previously been possible. Such fields are used for encoding information in data storage microelectronic devices. Since the world now generates more data than it can store, the search is on for new technologies to improve storage capacity and energy efficiency by encoding information at the smallest possible length scales. It is an ....Nanoscale field mapping in functional materials. This project aims to develop tools to map electric and magnetic fields within matter on smaller-length scales than has previously been possible. Such fields are used for encoding information in data storage microelectronic devices. Since the world now generates more data than it can store, the search is on for new technologies to improve storage capacity and energy efficiency by encoding information at the smallest possible length scales. It is anticipated that the new characterisation techniques resulting from this project will enable academic and industrial researchers working on the next generation of data storage technology to solve problems they could not otherwise solve.Read moreRead less
Enabling semiconductor nanowire technologies via 3D atomic-scale insight. Semiconductor nanowires (NWs) are nanotechnology building blocks that have the potential to transform solar cells, light emitting diodes, lasers and transistors, creating new industries in communications, energy and healthcare. The industrial development of NWs has been blocked by uncertainties in the relationships between their growth conditions, properties and atomic-scale structure. This project will address this chall ....Enabling semiconductor nanowire technologies via 3D atomic-scale insight. Semiconductor nanowires (NWs) are nanotechnology building blocks that have the potential to transform solar cells, light emitting diodes, lasers and transistors, creating new industries in communications, energy and healthcare. The industrial development of NWs has been blocked by uncertainties in the relationships between their growth conditions, properties and atomic-scale structure. This project will address this challenge by establishing a rigorous framework for these relationships. The project aims to achieve this by harnessing the unique power of atom probe microscopy to reveal the NW structure in three dimensions, and at atomic-resolution. The project aims to place Australian research at the frontier of development of these future industries.Read moreRead less
Making every electron count in atomic resolution microscopy. The development of aberration-corrected electron microscopy, which allows individual atom imaging with unprecedented precision, was recognised by the 2011 Wolf Prize in Physics. However, only a very limited amount of the wealth of information obtainable from such microscopes is currently exploited. By collecting a maximal data set of electrons scattered in manifold different ways and using the fundamental theory of electron-specimen in ....Making every electron count in atomic resolution microscopy. The development of aberration-corrected electron microscopy, which allows individual atom imaging with unprecedented precision, was recognised by the 2011 Wolf Prize in Physics. However, only a very limited amount of the wealth of information obtainable from such microscopes is currently exploited. By collecting a maximal data set of electrons scattered in manifold different ways and using the fundamental theory of electron-specimen interaction, this project will realise the huge potential of this untapped data. This will improve the utility of scanning transmission electron microscopy far beyond its current level. Applying these new techniques will expand our understanding of the structure and function of advanced materials.Read moreRead less
Manufacturing diamond membranes for quantum industries. Diamond materials are ideal for quantum technologies and are leading the charge in the new wave of real-world quantum industries. The aim of this project is to develop a reliable source of quantum-active diamond membranes to enable the development of new industries. This would be significant for technologies including quantum telecommunication, medical imaging and nano-scale quantum sensing. Of particular interest, expected outcomes include ....Manufacturing diamond membranes for quantum industries. Diamond materials are ideal for quantum technologies and are leading the charge in the new wave of real-world quantum industries. The aim of this project is to develop a reliable source of quantum-active diamond membranes to enable the development of new industries. This would be significant for technologies including quantum telecommunication, medical imaging and nano-scale quantum sensing. Of particular interest, expected outcomes include the development of materials for advanced medical imaging technologies. Successful development in any of these industries has the potential to greatly benefit society through improved healthcare, the development of new high-tech industries and advanced secure computing. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100336
Funder
Australian Research Council
Funding Amount
$416,899.00
Summary
Superconducting diamond for investigating sources of interface noise. This project aims to identify and eliminate the sources of electro-magnetic noise at material interfaces, through the development of diamond as a model semiconductor/superconductor material system. The project expects to generate new understandings about the origin of these noise sources, using a combination of new nanofabrication developments and exquisite control over the surface chemical bonding of the diamond material. Exp ....Superconducting diamond for investigating sources of interface noise. This project aims to identify and eliminate the sources of electro-magnetic noise at material interfaces, through the development of diamond as a model semiconductor/superconductor material system. The project expects to generate new understandings about the origin of these noise sources, using a combination of new nanofabrication developments and exquisite control over the surface chemical bonding of the diamond material. Expected outcomes include enhanced understanding and control of noise sources in superconducting and quantum devices, and potentially a new material platform for the creation of superconducting quantum circuits. By supporting Australia's nascent quantum technologies industry this project will help support research training and a higher quality workforce, with the possibility for enabling job creation in the future.Read moreRead less