Centre for Advanced Silicon Photovoltaics and Photonics. Silicon photovoltaics (Si PV) is a priority area within the Photon Science and Technology category. Multiple studies have identified PV solar electricity as the most promising option for a sustainable energy future, with Australia already at the forefront internationally in Si PV. The applicants recently have shown that insights from PV also may provide the key to the successful development of active Si photonic devices for integration i ....Centre for Advanced Silicon Photovoltaics and Photonics. Silicon photovoltaics (Si PV) is a priority area within the Photon Science and Technology category. Multiple studies have identified PV solar electricity as the most promising option for a sustainable energy future, with Australia already at the forefront internationally in Si PV. The applicants recently have shown that insights from PV also may provide the key to the successful development of active Si photonic devices for integration into microelectronics. The Centre's aims and expected outcomes are to strengthen this technological lead in Si PV while pioneering the development of active Si photonic devices for microelectronic integration, with economic, cultural and social benefits.Read moreRead less
Silicon Photonics and Third Generation Photovoltaics. The Fellowship would be used to launch a major new initiative addressing one of the key challenges facing microelectronics, the incorporation of optical functions into high density silicon integrated circuits, as well as accelerating development of a "third" generation of photovoltaic solar cells using similar techniques. This third generation thin-film technology would be capable of fundamentally higher energy conversion efficiency than ear ....Silicon Photonics and Third Generation Photovoltaics. The Fellowship would be used to launch a major new initiative addressing one of the key challenges facing microelectronics, the incorporation of optical functions into high density silicon integrated circuits, as well as accelerating development of a "third" generation of photovoltaic solar cells using similar techniques. This third generation thin-film technology would be capable of fundamentally higher energy conversion efficiency than earlier generations, at low cost. In both cases, the targeted outcome over the period of the Fellowship is to develop technology to the stage where it can be commercially evaluated, in a way likely to maximise Australian benefits.Read moreRead less
Development of a test bed for molecular memory and molecular photovoltaic devices. The development of nanostructured materials and the devices that utilize them is at the forefront of modern science and technology. Electrical devices whose functional units are structurally ordered single molecules dominate biochemical processes, especially pertinent ones being photosynthesis and cellular energy production; artificial devices promise new technologies in multi-$B markets such as long-term data st ....Development of a test bed for molecular memory and molecular photovoltaic devices. The development of nanostructured materials and the devices that utilize them is at the forefront of modern science and technology. Electrical devices whose functional units are structurally ordered single molecules dominate biochemical processes, especially pertinent ones being photosynthesis and cellular energy production; artificial devices promise new technologies in multi-$B markets such as long-term data storage and renewable solar-energy production. Interfacing molecules with macroscopic interconnects poses a great technological challenge, however, and in this project the underlying basic science will be determined through the formation of molecules into device-accessible functional materials.Read moreRead less
Molecular Electronics Principles and Applications. This project will establish basic conceptual models and computational methods to understand the nature of conduction, memory storage, and solar to electrical energy conversion processes in molecular devices on the 1-nanometer scale. Fundamental research of chemical processes, device interfaces, characterization techniques, and natural photosynthesis will result in widely applicable advances in nanotechnology. Additionally, novel architectures wi ....Molecular Electronics Principles and Applications. This project will establish basic conceptual models and computational methods to understand the nature of conduction, memory storage, and solar to electrical energy conversion processes in molecular devices on the 1-nanometer scale. Fundamental research of chemical processes, device interfaces, characterization techniques, and natural photosynthesis will result in widely applicable advances in nanotechnology. Additionally, novel architectures will be developed for disruptive new technologies in molecular memory and logic design, as well as in the design of biomimetic solar cells. These developments could lead to new Australian electronics industries and an order of magnitude reduction in the production cost of solar electricity.Read moreRead less
Special Research Initiatives - Grant ID: SR0354527
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Frontier technologies, prototypes and strategic positioning for the international radio telescope, the Square Kilometre Array. This Network will forge new linkages between scientists and engineers to design and enable an advanced prototype for the international next-generation radio telescope, the Square Kilometre Array (SKA). The prototype will make fundamental new tests of general relativity and the physics of dark energy and test SKA imaging and signal processing systems. The Network partners ....Frontier technologies, prototypes and strategic positioning for the international radio telescope, the Square Kilometre Array. This Network will forge new linkages between scientists and engineers to design and enable an advanced prototype for the international next-generation radio telescope, the Square Kilometre Array (SKA). The prototype will make fundamental new tests of general relativity and the physics of dark energy and test SKA imaging and signal processing systems. The Network partners will collaborate to develop low-cost technologies for ultra-wideband antennas, high-speed signal processing, software radios, mitigation of man-made interference and the handling of petabyte data sets. The aim is a leading role for Australian researchers and industry in the $2 billion SKA.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100048
Funder
Australian Research Council
Funding Amount
$340,000.00
Summary
Nanoscale optical microscopy facility. The optical microscope has enabled us to see micro-objects, leading to revolutionary discoveries in medicine and natural sciences. However, the smallest object resolved by a microscope is limited by the wavelength of light. To see nanoscale objects smaller than the wavelength, a new tool for nano-imaging is needed. This project will establish a nanoscale optical microscopy facility that will reveal the topology and true colours of the nano-objects. Such inf ....Nanoscale optical microscopy facility. The optical microscope has enabled us to see micro-objects, leading to revolutionary discoveries in medicine and natural sciences. However, the smallest object resolved by a microscope is limited by the wavelength of light. To see nanoscale objects smaller than the wavelength, a new tool for nano-imaging is needed. This project will establish a nanoscale optical microscopy facility that will reveal the topology and true colours of the nano-objects. Such information, achieved through spectroscopic analysis of the light emitted or scattered at the nanoscale, will uncover some of the most fundamental aspects of the nanoworld, leading to cutting-edge scientific discoveries and important industrial applications in photonics and solar energy.Read moreRead less
Tailored porphyrins for nanoscience applications. Porphyrins are the pigments of life, the central components of haemoglobin in blood and chlorophyll in living plants. In order to expand their use into important areas of nanoscience, this project will establish a new porphyrin paradigm. It will result in the synthesis of novel porphyrins with inbuilt structural features that enhance their propensity to self-assemble into monolayers on surfaces, and into nanorods. This will lead to advanced mate ....Tailored porphyrins for nanoscience applications. Porphyrins are the pigments of life, the central components of haemoglobin in blood and chlorophyll in living plants. In order to expand their use into important areas of nanoscience, this project will establish a new porphyrin paradigm. It will result in the synthesis of novel porphyrins with inbuilt structural features that enhance their propensity to self-assemble into monolayers on surfaces, and into nanorods. This will lead to advanced materials for molecular sensing, photonics, molecular memory devices, catalysis, and organic photovoltaics. A new means of improving the efficiency of solar cells will also be explored. Well-trained graduates and strong international scientific cooperation will also result from the project.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100116
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
Facilities of thermophysical characterisations at nanometre scale for development of advanced materials, energy technologies and biomedical components. Australia's energy, mining, metallurgical, defence, pharmaceutical and biomedical industries are spearheading the advancement of technologies in the global competitive market. They are the engines of Australian economic strength. Future progress of these industries will be largely driven by advances in materials. The installation of the propose ....Facilities of thermophysical characterisations at nanometre scale for development of advanced materials, energy technologies and biomedical components. Australia's energy, mining, metallurgical, defence, pharmaceutical and biomedical industries are spearheading the advancement of technologies in the global competitive market. They are the engines of Australian economic strength. Future progress of these industries will be largely driven by advances in materials. The installation of the proposed facilities will add a new dimension to high-level research performance and significantly enhance the capability for characterisation of various forms of materials and biomedical components in Australia. The continual development of advanced materials and energy technology will potentially provide a sustainable means for meeting the increasing global challenge for the industries.Read moreRead less
Molecular Electronics: from electron transfer through photosynthesis towards functional nano devices. Molecular Electronics, the use of molecules to perform specific electronic functions, is a new and very rapidly expanded area of nanotechnology. We will elucidate basic principles of electrical conduction through single molecules, understand and mimic natural photosynthetic molecular electronic processes, and establish by synthesis of "molecular wires" and extension of current technology, new m ....Molecular Electronics: from electron transfer through photosynthesis towards functional nano devices. Molecular Electronics, the use of molecules to perform specific electronic functions, is a new and very rapidly expanded area of nanotechnology. We will elucidate basic principles of electrical conduction through single molecules, understand and mimic natural photosynthetic molecular electronic processes, and establish by synthesis of "molecular wires" and extension of current technology, new methods for probing nanoscale electron transfer. We will combine these aspects to develop applications in photovoltaic design and in the design of molecular-level circuitry. Possible long-term applications range from solar energy conversion to molecular recognition and sensing to new types of electronic processing akin to quantum computing.Read moreRead less