Experimental mapping of electron densities in nano-structured materials. This project aims to map electrons in nano-structured materials using a new technique combining the latest solid-state theory with electron scattering experiments in one of the world’s most advanced electron microscopes. It is expected that by revealing the electronic structure of nano-scale features in bulk materials for the first time, their functions will become fully explainable. Aside from this new capability, other ....Experimental mapping of electron densities in nano-structured materials. This project aims to map electrons in nano-structured materials using a new technique combining the latest solid-state theory with electron scattering experiments in one of the world’s most advanced electron microscopes. It is expected that by revealing the electronic structure of nano-scale features in bulk materials for the first time, their functions will become fully explainable. Aside from this new capability, other expected outcomes include discovering how heat is converted into electricity in thermoelectric materials and how precipitates affect alloy strength. The benefits may include more informed materials design, more efficient thermoelectrics for sustainable energy technologies, and higher strength-to-weight ratio alloys.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100150
Funder
Australian Research Council
Funding Amount
$595,280.00
Summary
Advanced multifunctional photoelectron spectroscopy platform. This project aims to establish a new integrated facility that will allow researchers to characterise the surface structure and electronic properties of materials, which is essential for a complete understanding of their functionality. The development of the next generation of electronic, optical, and biomedical devices requires new materials with properties optimised for the particular application. This facility, to be housed in state ....Advanced multifunctional photoelectron spectroscopy platform. This project aims to establish a new integrated facility that will allow researchers to characterise the surface structure and electronic properties of materials, which is essential for a complete understanding of their functionality. The development of the next generation of electronic, optical, and biomedical devices requires new materials with properties optimised for the particular application. This facility, to be housed in state-of-the-art laboratories and managed as an open access resource, will meet the needs of a large number of innovative projects and enable advances in many fields including electronics, nanotechnology, solar energy, biotechnology and advanced materials.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100314
Funder
Australian Research Council
Funding Amount
$353,773.00
Summary
Engineering magnetism at the atomic scale in topological insulators. This project aims to explore strategies to optimise the magnetisation and Curie temperature by incorporating dopants via ion implantation, and exploiting proximity effects in heterostructures with magnetic thin films. The recently discovered magnetism in topological insulators opens up a new class of materials with potential applications in energy-efficient electronics, data storage and information processing. The central chall ....Engineering magnetism at the atomic scale in topological insulators. This project aims to explore strategies to optimise the magnetisation and Curie temperature by incorporating dopants via ion implantation, and exploiting proximity effects in heterostructures with magnetic thin films. The recently discovered magnetism in topological insulators opens up a new class of materials with potential applications in energy-efficient electronics, data storage and information processing. The central challenges are to control the underlying magnetic structure and stabilise magnetic order at desirable temperatures. The project expects to discover new composite materials and advance our knowledge for designing magnetic components in the next generation of electronics with ultra-low power dissipation.Read moreRead less
Electro-mechanics of natural load-bearing materials: understanding mechanisms of toughening, remodelling, and self-healing. Nature provides some of the most advanced functional structural materials, with the capability to remodel and strengthen under changing loads. The origins of the functional properties which allow them to do this will be explored, providing the possibility of developing materials which mimic this behaviour.
'Designer defects' - A new approach to functional oxide interfaces. The conventional approach to metal oxide interfaces is 'perfection at all costs' with growth tuned to minimise defects and unwanted chemical intermixing. This project aims to turn this approach on its head by creating interfaces with 'designer defects' that become the critical portion of a functional device. This project proposes that one can promote functionality by making use of new physical properties that arise from the deli ....'Designer defects' - A new approach to functional oxide interfaces. The conventional approach to metal oxide interfaces is 'perfection at all costs' with growth tuned to minimise defects and unwanted chemical intermixing. This project aims to turn this approach on its head by creating interfaces with 'designer defects' that become the critical portion of a functional device. This project proposes that one can promote functionality by making use of new physical properties that arise from the deliberate introduction of structural and electronic mismatches at an interface. Such purposely induced 'designer defects' in epitaxial oxide thin films will allow new properties to be achieved in nanoscale layers. This is expected to lead to a new class of functional materials to be used in sensors and nanoelectronics.Read moreRead less
Domain wall nanoelectronics : The wall is the device. This project investigates the nanofabrication and atomic-scale manipulation of domain walls in multiferroic oxide thin films. Proximal scanning probe writing in conjunction with nanolithography is exploited to precisely engineer domain wall configurations, to be used as functional elements. The experiments will be supported by the multiscale modeling theory of multiferroics. Domain wall control and engineering is proposed as the new paradigm ....Domain wall nanoelectronics : The wall is the device. This project investigates the nanofabrication and atomic-scale manipulation of domain walls in multiferroic oxide thin films. Proximal scanning probe writing in conjunction with nanolithography is exploited to precisely engineer domain wall configurations, to be used as functional elements. The experiments will be supported by the multiscale modeling theory of multiferroics. Domain wall control and engineering is proposed as the new paradigm for multiferroics used in future nanoelectronic devices. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100109
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
A multiscale electrochemical, magnetoelectric and electromechanical characterisation facility for advanced materials and devices. This infrastructure for advanced materials characterisation will boost Australia's capabilities in creating functional materials and nanostructured interfaces. It will yield new materials and functional interfaces with the best performance for applications in nanotechnology, communications, the environment and security.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100223
Funder
Australian Research Council
Funding Amount
$340,000.00
Summary
Advanced X-ray diffraction facility for high energy and extreme conditions. X-ray powder diffraction is a powerful technique for determining the structure of matter at the atomic scale. This project will establish a new Australian capability for X-ray powder diffraction under extreme conditions that emulate real harsh service environments for advanced functional materials.