Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100235
Funder
Australian Research Council
Funding Amount
$180,000.00
Summary
Interfacial mapping facility. New electronic materials and devices impact on everyday life in areas such as photovoltaics, biotechnology and healthcare. This facility will provide researchers with the unique capability of mapping both the structure and electronic properties of materials on the nanoscale. It will be an essential tool for developing new electronics based on nanotechnology.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100118
Funder
Australian Research Council
Funding Amount
$1,800,000.00
Summary
UltraTEM: Resolving the structure of matter in space, energy and time. This project aims to establish a transmission electron microscope facility to analyse materials structure at the atomic level. A small number of atoms in critical locations governs the properties of materials from solar cells and catalysts to aerospace alloys, bio-sensors and quantum computers. To understand and engineer matter at this atomic level, tools are needed to characterise these critical atoms. This open access, nati ....UltraTEM: Resolving the structure of matter in space, energy and time. This project aims to establish a transmission electron microscope facility to analyse materials structure at the atomic level. A small number of atoms in critical locations governs the properties of materials from solar cells and catalysts to aerospace alloys, bio-sensors and quantum computers. To understand and engineer matter at this atomic level, tools are needed to characterise these critical atoms. This open access, national facility will be able to characterise matter at the atomic-level. Expected outcomes include better understanding of the natural world and advanced materials to solve problems in energy, technology, health, environment, communications, advanced manufacturing, transport and security.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100020
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
High bandwidth, high speed, terahertz optical sampling and analysis system. This project aims to promote scientific and technological research by providing access to a wide bandwidth, high speed, high resolution advanced terahertz spectrometer. Terahertz frequencies are the least-explored region of the electromagnetic spectrum and investment here is likely to yield scientific and technological reward. Expected outcomes are new commercial devices and products operating in the terahertz regime. Th ....High bandwidth, high speed, terahertz optical sampling and analysis system. This project aims to promote scientific and technological research by providing access to a wide bandwidth, high speed, high resolution advanced terahertz spectrometer. Terahertz frequencies are the least-explored region of the electromagnetic spectrum and investment here is likely to yield scientific and technological reward. Expected outcomes are new commercial devices and products operating in the terahertz regime. The project’s expected effects include new commercial terahertz products; better monitoring of explosives and toxins; research training and job creation; reduced risk in decision making, especially when monitoring water; and cultural benefits, through applying terahertz methods to artworks.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100121
Funder
Australian Research Council
Funding Amount
$1,000,000.00
Summary
An analytical transmission electron microscope for the investigation of functional materials, earth processes and novel condensed matter. Sustainablity depends on the delivery of clean energy, pristine water and air, and the manufacture of consumer products with small environmental footprints. Modelling long-term impacts requires an understanding of the hydro-geological cycles. The technologies are well known—efficient electronics, fuel cells, lightweight composites, and so on—but delivery is ....An analytical transmission electron microscope for the investigation of functional materials, earth processes and novel condensed matter. Sustainablity depends on the delivery of clean energy, pristine water and air, and the manufacture of consumer products with small environmental footprints. Modelling long-term impacts requires an understanding of the hydro-geological cycles. The technologies are well known—efficient electronics, fuel cells, lightweight composites, and so on—but delivery is not straightforward. It is clear, however, that novel materials manipulated at fine scales will be key. Transmission electron microscopy (TEM) guides the development of sustainable technologies. The new TEM facility at ANU will accelerate current studies, by enhancing the materials research portfolio, and extending national and international collaborations in materials, geological and earth sciences.Read moreRead less
Synchrotron X-ray absorption fine structure and fundamental X-ray interactions for nano-physics, chemistry and mineralogy. This project will develop new synchrotron techniques for measuring and interpreting X-ray data from materials targeting the nano-environment and bonding. The first wave of synchrotron nanotechnology is nascent. The project's X-ray methods develop techniques in applied mineralogy and catalysis. New insight will address key questions in chemistry, mining and biology.
Unlocking the potential of quantitative x-ray micro-tomography. This project aims to build on two new ideas in data acquisition and 3D image reconstruction to bring 3D X-ray microscopy or computed tomography (CT) into advanced research use as well as common industrial applications. In the past 10 years, CT has improved our understanding in areas ranging from the evolution of life and osteoporosis to composite material failure and oil recovery. However, the full potential of CT remains unrealised ....Unlocking the potential of quantitative x-ray micro-tomography. This project aims to build on two new ideas in data acquisition and 3D image reconstruction to bring 3D X-ray microscopy or computed tomography (CT) into advanced research use as well as common industrial applications. In the past 10 years, CT has improved our understanding in areas ranging from the evolution of life and osteoporosis to composite material failure and oil recovery. However, the full potential of CT remains unrealised because crucial features in structure and composition are overlooked by simplistic algorithms. Users cannot directly capture quantities of interest such as key compositional variation or defects, and workflows are poorly adapted for large-scale use in industrial fabrication or phenomics. This project aims to address these shortcomings using advanced mathematics and algorithms.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100132
Funder
Australian Research Council
Funding Amount
$1,486,000.00
Summary
A triple beam microscope: new frontiers in materials nanocharacterisation. This project aims to establish a triple beam ion and electron microscope facility for the modification, preparation and characterisation of materials that have hitherto been too sensitive for high resolution analysis with charged particle beams. It is expected that materials will be studied artefact-free and at the nanoscale with twin ion beams and new detectors that allow novel imaging modes and extreme chemical sensitiv ....A triple beam microscope: new frontiers in materials nanocharacterisation. This project aims to establish a triple beam ion and electron microscope facility for the modification, preparation and characterisation of materials that have hitherto been too sensitive for high resolution analysis with charged particle beams. It is expected that materials will be studied artefact-free and at the nanoscale with twin ion beams and new detectors that allow novel imaging modes and extreme chemical sensitivity plus controlled atmosphere transfer to other instruments for correlative measurements. This unique facility should benefit research in many disciplines such as physics, chemistry, geology, pharmacy, materials, civil and chemical engineering by allowing first-ever observations of vital phenomena in diverse materials.Read moreRead less
Quantum microscopy meets photovoltaics: new tools for solar cell research. This project aims to create an innovative platform to characterise solar cells, based on recently developed quantum diamond microscopy. It will enable direct imaging of the current flow in operating photovoltaic devices, providing a new window into key processes such as charge collection and recombination. The platform will be applied to a range of industry-relevant photovoltaic materials and devices. Anticipated outcomes ....Quantum microscopy meets photovoltaics: new tools for solar cell research. This project aims to create an innovative platform to characterise solar cells, based on recently developed quantum diamond microscopy. It will enable direct imaging of the current flow in operating photovoltaic devices, providing a new window into key processes such as charge collection and recombination. The platform will be applied to a range of industry-relevant photovoltaic materials and devices. Anticipated outcomes include new insights into recombination processes and the effect of device degradation, which could facilitate optimisation of the power conversion efficiency and reliability of next-generation solar cells. Additional benefits include new instruments and methods that may find use in the solar cell manufacturing industry.Read moreRead less
Revealing the atoms that control performance in photoactive perovskites. This project aims to develop new electron microscopy techniques that will unambiguously determine the elusive structures of photoactive perovskite compounds under static and operational conditions, while correlating crystal structure with solar cell device performance. Photoactive perovskites are promising photovoltaic materials, however, many are sensitive to air and irradiation. This has impeded a huge international resea ....Revealing the atoms that control performance in photoactive perovskites. This project aims to develop new electron microscopy techniques that will unambiguously determine the elusive structures of photoactive perovskite compounds under static and operational conditions, while correlating crystal structure with solar cell device performance. Photoactive perovskites are promising photovoltaic materials, however, many are sensitive to air and irradiation. This has impeded a huge international research effort to determine their structure reliably at the atomic scale. With these new techniques applied to leading compounds and devices, it is expected this project will reveal the structural effects controlling electrical properties and device performance and so enable the design of superior perovskite photovoltaics.Read moreRead less
The science and engineering of defects and impurities in photovoltaic silicon. This project will create the knowledge and techniques that are essential to make low-cost, impure silicon suitable for producing highly efficient solar cells. This will help to drive down the cost of solar electricity, since the silicon material itself is a significant component of the overall cost of most photovoltaic modules.