New High Precision Tests on the Standard Model of Physics and Relativity. Precision microwave oscillators developed at UWA are among the most precise devices for testing the current theories in modern physics, such as relativity and the standard model. With new timely experiments in the laboratory at UWA and with our collaborators in France, we are searching for violations which may lead to a breakdown in the current understanding of physics. This project will strengthen Australian ?know how? an ....New High Precision Tests on the Standard Model of Physics and Relativity. Precision microwave oscillators developed at UWA are among the most precise devices for testing the current theories in modern physics, such as relativity and the standard model. With new timely experiments in the laboratory at UWA and with our collaborators in France, we are searching for violations which may lead to a breakdown in the current understanding of physics. This project will strengthen Australian ?know how? and expertise, which will place us in a position to participate in current and future space missions. Moreover, this represents an opportunity to be involved as the only southern hemisphere users of the most accurate space clock ever developed.Read moreRead less
Infrared optoelectronic sensors based on p-type molecular beam epitaxy grown HgCdTe. The ability of infrared detectors to directly sense the thermal output of an object has applications in medicine, search and rescue, bushfire detection and in the defence and surveillance industries. The highest performing infrared detectors are photon detectors based molecular beam epitaxy (MBE) grown HgCdTe. The primary aims of this project relate to the fundamental understanding of p-type doping in MBE grown ....Infrared optoelectronic sensors based on p-type molecular beam epitaxy grown HgCdTe. The ability of infrared detectors to directly sense the thermal output of an object has applications in medicine, search and rescue, bushfire detection and in the defence and surveillance industries. The highest performing infrared detectors are photon detectors based molecular beam epitaxy (MBE) grown HgCdTe. The primary aims of this project relate to the fundamental understanding of p-type doping in MBE grown HgCdTe, a current and major difficulty in HgCdTe technology, and the use of such p-type MBE grown layers in conjunction with a newly developed plasma process based n-p junction formation technology to realise novel and innovative infrared detector structures. Such structures would have the ability to revolutionise the use of HgCdTe in infrared detectors and focal plane array applications.Read moreRead less
New generation of hyperspectral infrared photon detectors. Although highly desirable for many applications, tuneable, on chip, infrared photon detectors are not yet available. The approach described in this application aims to develop a technology for high performance, on chip, infrared photon detectors that can be tuned over a wide wavelength range. By applying a novel in-house developed semiconductor process and a multi-disciplinary approach, this project aims to develop such devices by combin ....New generation of hyperspectral infrared photon detectors. Although highly desirable for many applications, tuneable, on chip, infrared photon detectors are not yet available. The approach described in this application aims to develop a technology for high performance, on chip, infrared photon detectors that can be tuned over a wide wavelength range. By applying a novel in-house developed semiconductor process and a multi-disciplinary approach, this project aims to develop such devices by combining, for the first time, micromachined tuneable optical microcavities with high performance HgCdTe-based infrared detectors.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775614
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
National Electromagnetic Characterization Facility for Advanced Electronic and Biomaterials. The proposed Material Characterisation Facility using non-destructive methods will be unique to Australia. Precise characterisation of advanced materials such as dielectrics and superconductors using the facility will progress emerging technologies within the electronic and communication research area. The inclusion of a microwave scanning test bed within the laboratory will allow engineers, scientists, ....National Electromagnetic Characterization Facility for Advanced Electronic and Biomaterials. The proposed Material Characterisation Facility using non-destructive methods will be unique to Australia. Precise characterisation of advanced materials such as dielectrics and superconductors using the facility will progress emerging technologies within the electronic and communication research area. The inclusion of a microwave scanning test bed within the laboratory will allow engineers, scientists, biologists and medical scientists to safely detect the intrinsic electromagnetic properties of electronic materials and tumours in biological tissues or poor quality agricultural produce. This comprehensive material characterisation facility will therefore benefit the peoples of Australasia in many significant and diverse ways.Read moreRead less
Composite magnetic conducting nanomaterials for microwave applications. Australian science and technology will be a leading participant in the creation of a new, useful technology for microwave and magnetologic applications whose properties arise from integration of metallic magnetic nanoelements with miniature nonmagnetic current conductors. Recent proof-of-concept demonstrations have inspired an explosion of activity on a global scale. In this project, young Australian scientists and research ....Composite magnetic conducting nanomaterials for microwave applications. Australian science and technology will be a leading participant in the creation of a new, useful technology for microwave and magnetologic applications whose properties arise from integration of metallic magnetic nanoelements with miniature nonmagnetic current conductors. Recent proof-of-concept demonstrations have inspired an explosion of activity on a global scale. In this project, young Australian scientists and research students will have opportunities to receive training and become involved in a National Priority Frontier Technology rich in possibilities for generation of intellectual property.Read moreRead less
Complex magnetic structures for microwave, logic and memory applications. The proposed work addresses high profile fields of nanotechnology and frequency agile materials. Device prototypes of novel energy efficient components for microwave signal processing, for wave logic and for memory applications based on magnetic materials will be designed, fabricated and studied.