Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100229
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
A prototype Scanning Helium Atom Microscope (SHeM) for soft materials. The scanning helium atom microscope (SHeM) has been a tantalising prospect since the birth of quantum physics. The SHeM would have unparalleled resolution and would be completely non-damaging; potentially revolutionising the imaging of soft delicate materials. This project will develop the first SHeM instrument in Australia to study soft matter.
Phonon based condensed matter imaging. This project will exploit observations of phonon-based chemical contrast in the SHeM to determine the physics that underpins the imaging mechanism and use them to probe vibrational processes in condensed matter imaging. Imaging is an essential tool for the discovery, application and fabrication of new materials, structures and devices. However, many delicate structures are irrevocably degraded and changed when imaged using conventional microscopy. This team ....Phonon based condensed matter imaging. This project will exploit observations of phonon-based chemical contrast in the SHeM to determine the physics that underpins the imaging mechanism and use them to probe vibrational processes in condensed matter imaging. Imaging is an essential tool for the discovery, application and fabrication of new materials, structures and devices. However, many delicate structures are irrevocably degraded and changed when imaged using conventional microscopy. This team recently invented the scanning helium atom microscope (SHeM), which can image surfaces non-destructively with nanoscale resolution. They will use the SHeM to determine the new fundamental physics that underpins the imaging mechanism. Outcomes include turning SHeM into a tool that materials and biological scientists can use in laboratories worldwide.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170101170
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Electronic structure on both sides of the Fermi level in molecular material. This project aims to develop an inverse photoemission spectrometer to elucidate the electronic properties of molecular materials. In tandem with traditional photoemission, the spectrometer will measure the electronic structure of small molecules for organic electronics and two-dimensional graphene-analogous polymers, providing information critical to their development and use. The instrument is expected to bring critica ....Electronic structure on both sides of the Fermi level in molecular material. This project aims to develop an inverse photoemission spectrometer to elucidate the electronic properties of molecular materials. In tandem with traditional photoemission, the spectrometer will measure the electronic structure of small molecules for organic electronics and two-dimensional graphene-analogous polymers, providing information critical to their development and use. The instrument is expected to bring critical insight to the burgeoning field of molecular materials, with potential widespread applications from energy conversion to sensing and electronics, with benefits across sectors.Read moreRead less
Chemical mapping of materials at the atomic scale. This project will develop a method for measuring the chemical composition of technologically important nanomaterials. This capability will provide Australian scientists with an advanced method for the characterisation of materials and will help them to develop new and better materials for future applications.
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
ARC Centre of Excellence in Advanced Molecular Imaging. The Centre of Excellence in Advanced Molecular Imaging will innovatively integrate physics, chemistry and biology to unravel the complex molecular interactions that define immunity. The Centre will develop new imaging methods to visualize atomic, molecular and cellular details of how immune proteins interact and
effect immune responses. Outcomes: (i) new technological innovations leading to new imaging methods and products; and (ii) fundame ....ARC Centre of Excellence in Advanced Molecular Imaging. The Centre of Excellence in Advanced Molecular Imaging will innovatively integrate physics, chemistry and biology to unravel the complex molecular interactions that define immunity. The Centre will develop new imaging methods to visualize atomic, molecular and cellular details of how immune proteins interact and
effect immune responses. Outcomes: (i) new technological innovations leading to new imaging methods and products; and (ii) fundamental advances in understanding details of immune responses in health and disease. The Centre will enable Australia to be an international leader in biological imaging, to train next
generation interdisciplinary scientists, and to provide new insights for combating common diseases that afflict society.Read moreRead less
Novel 2-photon atom manipulation for ultra-nanoscale processing of diamond. There is intense interest in exploiting diamond's remarkable properties in many fields of science and technology, but fabricating and processing devices remains a major challenge. This project will build on previous work, using a recently discovered novel laser-induced surface phenomenon that enables, for the first time for any material, the exciting prospect of using light to manipulate surface atoms with atomic precis ....Novel 2-photon atom manipulation for ultra-nanoscale processing of diamond. There is intense interest in exploiting diamond's remarkable properties in many fields of science and technology, but fabricating and processing devices remains a major challenge. This project will build on previous work, using a recently discovered novel laser-induced surface phenomenon that enables, for the first time for any material, the exciting prospect of using light to manipulate surface atoms with atomic precision. This project aims to elucidate the mechanisms underpinning the optical interaction to reveal its full potential and use it to address key problems in diamond nano-device fabrication that lie beyond the reach of current techniques. It is expected that the outcomes will directly enhance Australia's current strengths in diamond-based quantum and photonic technologies.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102069
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Optical solitons on a photonic chip: unprecedented light control at the nanoscale. Solitons, waves that maintain their shape as they travel, exist in systems as diverse as water waves, molecular biology, and optics. This project explores previously unobservable light propagation regimes in two-dimensional periodic media, photonic crystals. These studies provide unprecedented control of light-matter interaction at the nanoscale.
Surface modification of semiconducting organic charge transfer complexes with metal nanoparticles to create a new class of multifunctional materials. This project aims to deliver a facile and cheap method to produce a class of nanostructured composite materials to be used in applications which will have environmental and social benefits such as photocatalyst development for water purification, biosensing and the creation of antibacterial fabrics to prevent the spread of infection.