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
Applying advanced synchrotron radiation-based techniques to determine the connection between the geometric and electronic structure of semiconductor nanocrystals. As the dimensions of nanocrystals become small unique optical and electronic properties are observed, forming the basis of many new technologies. The properties of interest depend on the fine-scale, local details of the nanocrystal structure, which may differ considerably from bulk-like. Advanced synchrotron radiation techniques wil ....Applying advanced synchrotron radiation-based techniques to determine the connection between the geometric and electronic structure of semiconductor nanocrystals. As the dimensions of nanocrystals become small unique optical and electronic properties are observed, forming the basis of many new technologies. The properties of interest depend on the fine-scale, local details of the nanocrystal structure, which may differ considerably from bulk-like. Advanced synchrotron radiation techniques will be used to investigate the relationship between the local geometric and electronic structure of semiconductor nanocrystals. Insight will be provided to their formation and stability, and the important mechanisms of their unique optical and electronic properties will be identified. Such fundamental information is necessary to facilitate innovative application of future nanocrystal technology.Read moreRead less
Quantitative real-time imaging of high-temperature superconductors. This project will develop a robust technique for the quantitative real-time imaging of high-temperature superconductors. The image-analysis algorithm so obtained will be a virtual software lens, which is able to decode the information contained in data obtained by a well-established but hitherto qualitative imaging technique. We will transform this technique into one uniquely capable of obtaining two-dimensional movies of the ....Quantitative real-time imaging of high-temperature superconductors. This project will develop a robust technique for the quantitative real-time imaging of high-temperature superconductors. The image-analysis algorithm so obtained will be a virtual software lens, which is able to decode the information contained in data obtained by a well-established but hitherto qualitative imaging technique. We will transform this technique into one uniquely capable of obtaining two-dimensional movies of the current distributions, magnetic fields, and pinning defects in superconducting films. Such a quantitative characterization of these key superconductor parameters will be an important tool in the present global quest for room-temperature superconductivity.Read moreRead less
Boron nitride nanotubes for tunable conductivity. The proposed research in nanotubes falls into the national research priority areas of advanced materials and breakthrough science. This ANU research group has a leading role in Boron Nitride (BN) nanotube research internationally. The proposed collaborative research will enhance this position and further improve the nation's research profile in nanotechnology. New intellectual properties will be generated if the project is successful, which wi ....Boron nitride nanotubes for tunable conductivity. The proposed research in nanotubes falls into the national research priority areas of advanced materials and breakthrough science. This ANU research group has a leading role in Boron Nitride (BN) nanotube research internationally. The proposed collaborative research will enhance this position and further improve the nation's research profile in nanotechnology. New intellectual properties will be generated if the project is successful, which will benefit the commercialization activity of BN nanotubes at ANU. New PhD and undergraduate students will be trained by the proposed cutting edge research project.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882878
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
Facility for imaging, manipulation and measurement of molecular-scale quantum materials. The development of functional electronic devices relies on understanding how properties on the atomic-scale influence the performance of new device materials. We will develop the capability to image and manipulate surfaces, and enable new protocols for probing the quantum properties of a wide range of materials that cannot currently be accessed at the molecular-level. By facilitating studies of important eme ....Facility for imaging, manipulation and measurement of molecular-scale quantum materials. The development of functional electronic devices relies on understanding how properties on the atomic-scale influence the performance of new device materials. We will develop the capability to image and manipulate surfaces, and enable new protocols for probing the quantum properties of a wide range of materials that cannot currently be accessed at the molecular-level. By facilitating studies of important emerging materials such as diamond, fullerenes and magnetic molecules, the facility aims to place Australia at the forefront of new areas of surface and device science, and to develop new devices for quantum metrology, information and molecular detection within frontier quantum industries.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0454166
Funder
Australian Research Council
Funding Amount
$1,305,029.00
Summary
Nanoscale Materials Characterization Facility. We request a transmission and a scanning electron microscope, each with specialist electron probes smaller than a nanometre, which can selectively analyse the atomic structure and chemistry of sub-nanometre regions of material.
These capabilities are essential to advance a large range of research projects at the cutting-edge of materials science and engineering, undertaken by Victoria's leading research institutions: five Victorian universities, ....Nanoscale Materials Characterization Facility. We request a transmission and a scanning electron microscope, each with specialist electron probes smaller than a nanometre, which can selectively analyse the atomic structure and chemistry of sub-nanometre regions of material.
These capabilities are essential to advance a large range of research projects at the cutting-edge of materials science and engineering, undertaken by Victoria's leading research institutions: five Victorian universities, the CSIRO, Nanotechnology Victoria Ltd, the Victorian Centre for Advanced Materials Manufacturing and the CRC for Microtechnology. Together they have contributed $2.58 million to this project.
This state-of-the-art facility will include the highest spatial resolution microscope in Australia.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775545
Funder
Australian Research Council
Funding Amount
$445,000.00
Summary
Infrastructure for Surface and Molecular-level Electronic and Spintronic Materials Measurement. It is recognised that molecular-state materials will play an important role in the development of new approaches to metrology, information processing and sensitive detection. Building on our existing expertise and infrastructure for nanoscale fabrication and surface analysis, we will develop a measurement capability for the study of atomic-scale and molecular-state materials, such as doped fullerenes, ....Infrastructure for Surface and Molecular-level Electronic and Spintronic Materials Measurement. It is recognised that molecular-state materials will play an important role in the development of new approaches to metrology, information processing and sensitive detection. Building on our existing expertise and infrastructure for nanoscale fabrication and surface analysis, we will develop a measurement capability for the study of atomic-scale and molecular-state materials, such as doped fullerenes, bio-materials, magnetic molecules, single implanted atoms and isolated optical centres, which show great promise for breakthrough fundamental science and the application of quantum phenomena to frontier nanoelectronics industries.Read moreRead less
Quantum transport in carbon-based materials. Carbon-based molecular materials will play an important role to frontier nanoelectronics industries. Building on our existing expertise and infrastructure for nanoscience, and employing new facilities at the Australian synchrotron, we aim to develop a unique approach to molecular-scale quantum device engineering utilising pure-carbon materials. New protocols for materials control of electronic structure at the molecular level will be developed to demo ....Quantum transport in carbon-based materials. Carbon-based molecular materials will play an important role to frontier nanoelectronics industries. Building on our existing expertise and infrastructure for nanoscience, and employing new facilities at the Australian synchrotron, we aim to develop a unique approach to molecular-scale quantum device engineering utilising pure-carbon materials. New protocols for materials control of electronic structure at the molecular level will be developed to demonstrate carbon as a quantum material, a high profile objective that will place Australia at the forefront of a new area of surface and device science. Read moreRead less
Template-Directed Growth and Assembly of Nanoscale Graphitic Carbon Structures. The various nanometre-scale forms of graphitic carbon have been strong candidates for use as novel building blocks in electronic, opto-electronic and electro-mechanical devices. However, their development has been hampered by a lack of control of the type, quality and homogeneity of structures produced by conventional methods.
This project aims to fabricate and characterise thin films of ordered, high-quality carbon ....Template-Directed Growth and Assembly of Nanoscale Graphitic Carbon Structures. The various nanometre-scale forms of graphitic carbon have been strong candidates for use as novel building blocks in electronic, opto-electronic and electro-mechanical devices. However, their development has been hampered by a lack of control of the type, quality and homogeneity of structures produced by conventional methods.
This project aims to fabricate and characterise thin films of ordered, high-quality carbon nanostructures. A novel synthesis route, involving the controlled deposition of carbon onto template substrates, is proposed. The products will be studied with near-atomic resolution to understand their formation mechanisms, and hence approach the goal of elaborating carbon-based nanodevices.
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Unlocking exceptional properties through pressure-induced phase transitions. The aim of this project is to produce novel hybrid boron nitride materials by utilizing advanced green techniques of mechanochemistry and high-pressure methods to achieve a phase transition from hexagonal to wurtzite structure. The development of these materials is critical in tackling contemporary environmental and technological issues, particularly those linked to cooling systems in electronic devices and batteries. T ....Unlocking exceptional properties through pressure-induced phase transitions. The aim of this project is to produce novel hybrid boron nitride materials by utilizing advanced green techniques of mechanochemistry and high-pressure methods to achieve a phase transition from hexagonal to wurtzite structure. The development of these materials is critical in tackling contemporary environmental and technological issues, particularly those linked to cooling systems in electronic devices and batteries. The outcome of this study will be new nanomaterials with exceptional mechanical, thermal, and electronic properties, as well as new insights into mechanical-force induced green chemistry and an environmentally friendly synthesis process, and help with heat management, energy preservation, and advanced manufacturing.Read moreRead less