Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0239650
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Advanced instrumentation for nano-scale imaging and analysis. It is widely accepted that the emerging fields of Nanotechnology and Nanoengineering will dominate research activity in a wide range of disciplines over the next decade. Progress in nanoscience and technology requires parallel development in nanocharacterisation and nanofabrication techniques. This proposal seeks to enhance the level of research infrastructure support for nano-scale microscopy and microanalysis at UTS and the Univer ....Advanced instrumentation for nano-scale imaging and analysis. It is widely accepted that the emerging fields of Nanotechnology and Nanoengineering will dominate research activity in a wide range of disciplines over the next decade. Progress in nanoscience and technology requires parallel development in nanocharacterisation and nanofabrication techniques. This proposal seeks to enhance the level of research infrastructure support for nano-scale microscopy and microanalysis at UTS and the University of Sydney by providing the following advanced instrumentation for nano-scale imaging, analysis and manipulation of materials:
- A Schottky field emission gun environmental scanning electron microscope
- Equipment kit for the rapid preparation of high quality transmission electron microscope specimens.Read moreRead less
Development of room temperature diluted magnetic semiconductors for spintronics devices application. Semiconductor spintronics is very likely to have a significant impact on future generations of devices. Until recently, Australian research groups have played a minor role in the field. The proposed program will lead to new discoveries or fundamental advances within semiconductor spintronics or have substantial impact on the progress in this field. The accomplishments of this project can great ....Development of room temperature diluted magnetic semiconductors for spintronics devices application. Semiconductor spintronics is very likely to have a significant impact on future generations of devices. Until recently, Australian research groups have played a minor role in the field. The proposed program will lead to new discoveries or fundamental advances within semiconductor spintronics or have substantial impact on the progress in this field. The accomplishments of this project can greatly increase the scientific understanding of diluted magnetic semiconductors and expand Australia's knowledge base in research in these materials. This program can also be an education platform to provide a number of scientific talents for Australia by intensively training high quality postgraduates at the international level.Read moreRead less
Some Outstanding Mechanics Problems in Layered Ferroelectromagnetic Composites with Enhanced Magnetoelectric Effect. The proposed research has high impact on both science and technology of ferroelectromagnetic materials. The outcomes will expand Australia's knowledge base and research capability in this emerging field. Relevant industries, such as smart materials and devices, can benefit from the results of this project. The theoretical, experimental and numerical results can be directly transfo ....Some Outstanding Mechanics Problems in Layered Ferroelectromagnetic Composites with Enhanced Magnetoelectric Effect. The proposed research has high impact on both science and technology of ferroelectromagnetic materials. The outcomes will expand Australia's knowledge base and research capability in this emerging field. Relevant industries, such as smart materials and devices, can benefit from the results of this project. The theoretical, experimental and numerical results can be directly transformed to design and application guidelines for the materials engineers and scientists to develop innovative and structurally/functionally reliable ferroelectromagnetic composites and their various devices and products.Read moreRead less
Development of growth strategies to fabricate wide band gap ferromagnetic semiconductors for spin electronics applications. Spin Electronics technology will enable a revolutionary class of electronic devices. Gallium nitride (GaN) containing transition metals (TM) (eg Mn, Ni and Fe) is a very promising dilute magnetic semiconductor for practical spintronics applications as this material exhibits magnetic behaviour above room temperature. However, electronic and magnetic properties of this new cl ....Development of growth strategies to fabricate wide band gap ferromagnetic semiconductors for spin electronics applications. Spin Electronics technology will enable a revolutionary class of electronic devices. Gallium nitride (GaN) containing transition metals (TM) (eg Mn, Ni and Fe) is a very promising dilute magnetic semiconductor for practical spintronics applications as this material exhibits magnetic behaviour above room temperature. However, electronic and magnetic properties of this new class of semiconductors have not yet been optimised. This project aims to develop and test a new growth strategy, known as the co-doping method for the fabrication of high quality TM doped GaN. A broad range of complementary advanced spectroscopic techniques will be used to evaluate and refine this new fabrication method.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101454
Funder
Australian Research Council
Funding Amount
$359,446.00
Summary
High performance lead-free piezoelectrics based on polar nanoregions. This project aims to enhance the electro-mechanical couplings of lead free piezoelectrics via introducing polar nanoregions for medical transducers applications. This is expected to impact on the design and development of high-performance lead free piezoelectrics, and have environmental benefits through replacing lead based counterparts.
Exploring the Dynamics of Nanostructure Self-Organisation during Compound Semiconductor Epitaxy. The application of LEEM to GaAs and InAs will be a world first, positioning Australia at the forefront of nanoscale self-organisation, leading to important international recognition and publicity. The spectacular movies obtained will revolutionise our basic understanding of compound semiconductor self-organisation and facilitate an improved control over nanostructure fabrication using MBE. This will ....Exploring the Dynamics of Nanostructure Self-Organisation during Compound Semiconductor Epitaxy. The application of LEEM to GaAs and InAs will be a world first, positioning Australia at the forefront of nanoscale self-organisation, leading to important international recognition and publicity. The spectacular movies obtained will revolutionise our basic understanding of compound semiconductor self-organisation and facilitate an improved control over nanostructure fabrication using MBE. This will generate entirely new device structures relevant to the frontier technologies of photonics and quantum information processing. The project will provide high level training for post-graduate and honours students in nanoscale characterisation and synchrotron science.Read moreRead less
Co-doping and transition metal doping of Gallium Nitride. Spintronics is poised to create a new paradigm in device electronics. Gallium nitride (GaN) containing trace amounts of transition metals (such as Fe,Ni) is a promising dilute magnetic semiconductor for spintronics as this material exhibits magnetic behaviour above room temperature. However, the electronic and magnetic properties of these GaN-based semiconductors have not been optimized, as yet. This project aims to establish and test a n ....Co-doping and transition metal doping of Gallium Nitride. Spintronics is poised to create a new paradigm in device electronics. Gallium nitride (GaN) containing trace amounts of transition metals (such as Fe,Ni) is a promising dilute magnetic semiconductor for spintronics as this material exhibits magnetic behaviour above room temperature. However, the electronic and magnetic properties of these GaN-based semiconductors have not been optimized, as yet. This project aims to establish and test a new growth strategy, know as the co-doping method, for the fabricate of high quality transition metal doped GaN. A broad range of complementary spectroscopic techniques will be used to refine this new fabrication technique.Read moreRead less
Application of First-principles Theory in Condensed Matter Physics, Surface Physics, Chemistry, and Engineering: Coatings, Catalysis, and Devices. The project addresses areas of high technological interest, namely the development of nitride-based materials for hard-coatings, spintronic (control and use of electron spin) and optoelectronic (in the blue/UV energy range) devices - as well as the area of heterogeneous oxidation catalysis. Using state-of-the-art methods it will lead to the developme ....Application of First-principles Theory in Condensed Matter Physics, Surface Physics, Chemistry, and Engineering: Coatings, Catalysis, and Devices. The project addresses areas of high technological interest, namely the development of nitride-based materials for hard-coatings, spintronic (control and use of electron spin) and optoelectronic (in the blue/UV energy range) devices - as well as the area of heterogeneous oxidation catalysis. Using state-of-the-art methods it will lead to the development of new materials and devices of relevance to industry.Read moreRead less
Development of direct-write focussed electron beam processing techniques for nano-fabrication applications. The burgeoning disciplines of nanotechnology and biotechnology have the potential to deliver breakthroughs in science and engineering that will revolutionise many aspects of everyday life. Progress in these emerging fields, however, requires parallel advances in the techniques used to fabricate, manipulate and characterise materials and devices at the nanoscale. This project will provide s ....Development of direct-write focussed electron beam processing techniques for nano-fabrication applications. The burgeoning disciplines of nanotechnology and biotechnology have the potential to deliver breakthroughs in science and engineering that will revolutionise many aspects of everyday life. Progress in these emerging fields, however, requires parallel advances in the techniques used to fabricate, manipulate and characterise materials and devices at the nanoscale. This project will provide such enabling tools and fill a major gap in the research infrastructure urgently required by these exciting new technologies.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101167
Funder
Australian Research Council
Funding Amount
$315,000.00
Summary
3D-printed hierarchical polymer metacomposites for microwave cloaking. The project aims to develop a metacomposite for microwave cloaking, constituted by soft ferromagnetic microwires using a 3D printing technique. The resultant light weight composite is expected to have a gradient index with the control of composite mesostructure, which is expected to be possible with an automatic engineering process without involvement of any high-cost nanofabrication process. Using a graded metacomposite as a ....3D-printed hierarchical polymer metacomposites for microwave cloaking. The project aims to develop a metacomposite for microwave cloaking, constituted by soft ferromagnetic microwires using a 3D printing technique. The resultant light weight composite is expected to have a gradient index with the control of composite mesostructure, which is expected to be possible with an automatic engineering process without involvement of any high-cost nanofabrication process. Using a graded metacomposite as a building block, a microwave cloak can be made that would make any objects beneath it invisible to microwave vigilant devices such as radar detection. The proposed metacomposite therefore has potential applications in military defence technology, aerospace and space exploration.Read moreRead less