Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560658
Funder
Australian Research Council
Funding Amount
$481,533.00
Summary
Shared Laser Facility. The Australian Shared Laser Facility (ASLF) has been providing lasers for physical chemistry research for a decade. ASLF lasers are portable and are transported between participating laboratories according to need and research priorities. Funds are sought to expand the ASLF by 3 laser systems and 2 research groups. The requested lasers provide mid-IR and deep UV wavelengths, spectral regions inaccessible with existing ASLF lasers. Access to these wavelengths is essenti ....Shared Laser Facility. The Australian Shared Laser Facility (ASLF) has been providing lasers for physical chemistry research for a decade. ASLF lasers are portable and are transported between participating laboratories according to need and research priorities. Funds are sought to expand the ASLF by 3 laser systems and 2 research groups. The requested lasers provide mid-IR and deep UV wavelengths, spectral regions inaccessible with existing ASLF lasers. Access to these wavelengths is essential for Australian research to remain at the forefront of international physical chemistry research. ASLF laboratories support a wide range of chemical research including spectroscopy, environmental chemistry, astrochemistry, and exploration of nanostructured materials.Read moreRead less
Measuring the linewidth enhancement factor and optical feedback level factor of semiconductor lasers based on optical feedback self-mixing interferometry. This project aims to develop a high performance solution for the challenging problem of measuring the linewidth enhancement factor (LEF) of semiconductor lasers (SLs) and the optical feedback level factor, C, for the optical feedback self-mixing (OFSM) systems. Specific outcomes of the research include (1) a new model for an optical feedback ....Measuring the linewidth enhancement factor and optical feedback level factor of semiconductor lasers based on optical feedback self-mixing interferometry. This project aims to develop a high performance solution for the challenging problem of measuring the linewidth enhancement factor (LEF) of semiconductor lasers (SLs) and the optical feedback level factor, C, for the optical feedback self-mixing (OFSM) systems. Specific outcomes of the research include (1) a new model for an optical feedback self-mixing effect, (2) a new approach for measuring LEF and C based on the proposed model, (3) signal processing algorithms for improving the performance of the proposed approach, and (4) an OFSM system prototype based on the new model and algorithms.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883030
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
High-Resolution Field Emission Scanning Electron Microscopy (FESEM) Platform for Characterisation at the Nanometre-Level. The Field Emission Scanning Electron Microscope (FESEM) is designed to provide fundamental insights into physical and biological systems though characterisation and analysis of structures on nanometre length scales. This versatile instrument will support a wide range of research projects covering all four national research priorities. These range from the characterisation of ....High-Resolution Field Emission Scanning Electron Microscopy (FESEM) Platform for Characterisation at the Nanometre-Level. The Field Emission Scanning Electron Microscope (FESEM) is designed to provide fundamental insights into physical and biological systems though characterisation and analysis of structures on nanometre length scales. This versatile instrument will support a wide range of research projects covering all four national research priorities. These range from the characterisation of light alloys to boost and intensify Australia's aluminium, magnesium and titanium alloy industries, to tissue engineering for the repair of human elastic tissues in skin, artery, bladder and lung, to the study of microtubules in plant cells for genetic manipulation of plants to withstand environmental stresses such as drought or salinity.Read moreRead less
Astrophotonics: exploiting a new technological frontier to probe back to the Dark Ages. Photonics, a key research strength in Australia, emerged from the telecommunications industry. But this exciting field has now begun to foster new scientific disciplines. One of the most recent is astrophotonics, a field at the interface of photonics and another Australian research strength, astronomy. Astrophotonics will deliver cutting-edge technologies to ensure Australia's astronomical lead in the next de ....Astrophotonics: exploiting a new technological frontier to probe back to the Dark Ages. Photonics, a key research strength in Australia, emerged from the telecommunications industry. But this exciting field has now begun to foster new scientific disciplines. One of the most recent is astrophotonics, a field at the interface of photonics and another Australian research strength, astronomy. Astrophotonics will deliver cutting-edge technologies to ensure Australia's astronomical lead in the next decade. These new facilities will serve as a vital stepping stone to the Giant Magellan Telescope, a $500M project promising enormous economic, engineering and scientific opportunities for Australia. Astrophotonics will also lead to innovative technology transfer to fields such as medical science, optical computing and sensor technology.Read moreRead less
Gamma-ray burst astronomy in the Swift era and beyond. The study of gamma-ray bursts is one of the most active and exciting fields in astrophysics, and touches on subjects that are of interest to all humans: e.g., to what extent was life on Earth shaped by cataclysmic explosions in our Galaxy? Australia's ROTSE-III telescope is the only facility in the southern hemisphere capable of rapidly (within 10 seconds) finding optical light from gamma-ray bursts. It will provide Australian astronomers ....Gamma-ray burst astronomy in the Swift era and beyond. The study of gamma-ray bursts is one of the most active and exciting fields in astrophysics, and touches on subjects that are of interest to all humans: e.g., to what extent was life on Earth shaped by cataclysmic explosions in our Galaxy? Australia's ROTSE-III telescope is the only facility in the southern hemisphere capable of rapidly (within 10 seconds) finding optical light from gamma-ray bursts. It will provide Australian astronomers with a competitive advantage in this high-profile field. The project will involve and inspire some of our best physics and engineering students.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775546
Funder
Australian Research Council
Funding Amount
$370,000.00
Summary
Construction of the blue-arm of the ANU 2.3m telescope Wide-Field Spectrograph. The new blue and red arms of the WiFeS spectrograph on the SSO 2.3m telescope utilizes new optical techniques and advances in detector technology to provide unique capabilities for front-line research and student training. The novel integral field units on WiFeS extract spectra across the face of faint, distant galaxies enabling the dynamics of the stellar and gas content to be analysed in unprecedented detail. Anoth ....Construction of the blue-arm of the ANU 2.3m telescope Wide-Field Spectrograph. The new blue and red arms of the WiFeS spectrograph on the SSO 2.3m telescope utilizes new optical techniques and advances in detector technology to provide unique capabilities for front-line research and student training. The novel integral field units on WiFeS extract spectra across the face of faint, distant galaxies enabling the dynamics of the stellar and gas content to be analysed in unprecedented detail. Another important project will be to follow-up interesting objects discovered by the new SkyMapper telescope and establish those that need to be observed on 8 m telescopes such as Gemini, Magellan or VLT. Read moreRead less
Structure-Activity Relationships in Silicon-based Photovoltaics Through Atomic Scale Microscopy. This project aims to develop new design principles for silicon-based photovoltaics (PVs) through a comprehensive study of atomic-scale structures and phenomena in PV materials. The development of more efficient photovoltaic materials is of major global importance, given the pressing need for clean and renewable sources of energy. Australia has international leadership in developing solar cell technol ....Structure-Activity Relationships in Silicon-based Photovoltaics Through Atomic Scale Microscopy. This project aims to develop new design principles for silicon-based photovoltaics (PVs) through a comprehensive study of atomic-scale structures and phenomena in PV materials. The development of more efficient photovoltaic materials is of major global importance, given the pressing need for clean and renewable sources of energy. Australia has international leadership in developing solar cell technologies, and the ideal natural environment to exploit these technologies. The fundamental insights derived in this project, such as detailed 3D maps of dopant distributions at the atomic scale, will bolster Australia's international reputation in the field and provide better control in the design of PV devices. Read moreRead less
Characterisation, development and application of novel Ion Beam technology (IBT) to enhance the optical thin film manufacturing process. Manufacture of optical thin film coatings is a difficult and generally inefficient process undertaken within a vacuum chamber. There are many variables which are not easily controlled nor understood in these complex thermodynamic environments. This project aims to advance core knowledge in three critical areas namely an improved understanding of ion beam phy ....Characterisation, development and application of novel Ion Beam technology (IBT) to enhance the optical thin film manufacturing process. Manufacture of optical thin film coatings is a difficult and generally inefficient process undertaken within a vacuum chamber. There are many variables which are not easily controlled nor understood in these complex thermodynamic environments. This project aims to advance core knowledge in three critical areas namely an improved understanding of ion beam physics, new knowledge of the thermodynamic environment used in physical vapour deposition of thin films and new knowedge in the application of Ion beam Technology to optical thin film growth and characteristics.
This project is significant, developing core knowledge and understanding with potential to lead to process efficiency gains, improved optical film characteristics and accessing new areas of research (rf/photoic devices). This project will advance the current state of art in the field of Ion Beam Technology and Ion Beam assisted physical vapour deposition.
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