Discovery Early Career Researcher Award - Grant ID: DE160101167
Funder
Australian Research Council
Funding Amount
$315,000.00
Summary
3D-printed hierarchical polymer metacomposites for microwave cloaking. The project aims to develop a metacomposite for microwave cloaking, constituted by soft ferromagnetic microwires using a 3D printing technique. The resultant light weight composite is expected to have a gradient index with the control of composite mesostructure, which is expected to be possible with an automatic engineering process without involvement of any high-cost nanofabrication process. Using a graded metacomposite as a ....3D-printed hierarchical polymer metacomposites for microwave cloaking. The project aims to develop a metacomposite for microwave cloaking, constituted by soft ferromagnetic microwires using a 3D printing technique. The resultant light weight composite is expected to have a gradient index with the control of composite mesostructure, which is expected to be possible with an automatic engineering process without involvement of any high-cost nanofabrication process. Using a graded metacomposite as a building block, a microwave cloak can be made that would make any objects beneath it invisible to microwave vigilant devices such as radar detection. The proposed metacomposite therefore has potential applications in military defence technology, aerospace and space exploration.Read moreRead less
Hybrid materials with tunable mechanical response via topological interlocking and embedded kinematic agents. The project investigates a new approach to materials design targeting the inner architecture of materials. Such materials will be multifunctional and responsive to external fields. Applications include sound- and vibration-absorbing cladding, morphing aerospace and automotive materials, and protective civil engineering structures.
Defect engineering in molecular beam epitaxy-grown mercury cadmium telluride. This project aims to develop high quality mercury cadmium telluride (HgCdTe) materials with lower defect density and lower background doping levels. This will enable future, high-performance, lower-cost infrared sensors with the unique features of higher yield, larger array size and higher operating temperature. The project will generate new science and technologies on defect engineering in the epitaxial growth of sem ....Defect engineering in molecular beam epitaxy-grown mercury cadmium telluride. This project aims to develop high quality mercury cadmium telluride (HgCdTe) materials with lower defect density and lower background doping levels. This will enable future, high-performance, lower-cost infrared sensors with the unique features of higher yield, larger array size and higher operating temperature. The project will generate new science and technologies on defect engineering in the epitaxial growth of semiconducting HgCdTe on cadmium zinc telluride (CdZnTe) substrates. This will contribute to the development of core Australian industry sectors such as defence, environmental monitoring, medical imaging, earth remote sensing, mining, and oil and gas.Read moreRead less
Bandgap engineered mercury cadmium telluride heterostructures on gallium antimonide alternative substrates. This project aims to develop bandgap engineered mercury cadmium telluride heterostructures on gallium antimonide alternative substrates to enable high performance lower-cost infrared sensors with high yield, large array size, multiband detection and higher operating temperature. High performance infrared sensors and systems are core enabling technologies in civilian and defence application ....Bandgap engineered mercury cadmium telluride heterostructures on gallium antimonide alternative substrates. This project aims to develop bandgap engineered mercury cadmium telluride heterostructures on gallium antimonide alternative substrates to enable high performance lower-cost infrared sensors with high yield, large array size, multiband detection and higher operating temperature. High performance infrared sensors and systems are core enabling technologies in civilian and defence applications such as remote sensing, environmental monitoring, night vision and national security. This project expects to research into defect generation mechanisms in epitaxial growth of semiconducting mercury cadmium telluride on lattice mismatched substrates. This is expected to contribute to Australian industry sectors, thereby benefiting the Australian economy, society, environment, and national security.Read moreRead less
HgCdSe: A novel II-VI semiconductor material for next generation infrared technologies. High performance infrared sensors and systems represent core technologies in various civilian and defence applications such as remote sensing, environment monitoring, night vision and national security. The goal of this project is to develop new mercury cadmium selenide-based materials on gallium antimonide substrates for future high performance infrared sensors with the unique features of low cost, large arr ....HgCdSe: A novel II-VI semiconductor material for next generation infrared technologies. High performance infrared sensors and systems represent core technologies in various civilian and defence applications such as remote sensing, environment monitoring, night vision and national security. The goal of this project is to develop new mercury cadmium selenide-based materials on gallium antimonide substrates for future high performance infrared sensors with the unique features of low cost, large array size, room temperature operation as well as multiband detection. The outcomes of this project will lead to new science and next generation infrared sensors of benefit to Australian industry and defence technology. Read moreRead less
Printable technologies for high security documents and consumer products. Printable technologies for high security documents and consumer products. This project aims to develop two next-generation printable security feature technologies to protect users from counterfeiting, which costs the world economy billions in lost revenue and undermines the security of citizens. First, it aims to enhance the security of banknotes by developing printable active device patches with energy harvesting flexible ....Printable technologies for high security documents and consumer products. Printable technologies for high security documents and consumer products. This project aims to develop two next-generation printable security feature technologies to protect users from counterfeiting, which costs the world economy billions in lost revenue and undermines the security of citizens. First, it aims to enhance the security of banknotes by developing printable active device patches with energy harvesting flexible polymers as a power source and thin film graphene/polymer nanomaterial as an electrode/energy storage media. Second, it aims to design invisible carbon nanotube inks for optical authentication via near infrared activation. Both technologies are expected to thwart sophisticated counterfeits, particularly those supported by organised crime.Read moreRead less
Vapour phase detection of chemical warfare agents. This project aims to create luminescent plastic optoelectronic materials that can detect airborne chemical warfare agents, particularly nerve agents. Such agents are often odourless and invisible at lethal concentrations, so technology must detect and identify them before exposure. The intended outcomes are design rules for sensitive and selective materials that can be used in a handheld infield detector to sense chemical warfare agents based on ....Vapour phase detection of chemical warfare agents. This project aims to create luminescent plastic optoelectronic materials that can detect airborne chemical warfare agents, particularly nerve agents. Such agents are often odourless and invisible at lethal concentrations, so technology must detect and identify them before exposure. The intended outcomes are design rules for sensitive and selective materials that can be used in a handheld infield detector to sense chemical warfare agents based on the materials’ photophysical properties, and new analytical methods and sensing protocols. This research will be of interest to security agencies in Australia and internationally, and will better protect our military.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100042
Funder
Australian Research Council
Funding Amount
$190,000.00
Summary
UV to mid-infrared fluorescence spectrometer for use in mineral analysis, radiation dosimetry, and laser materials characterisation. Ultraviolet to mid-infrared fluorescence spectrometer for use in mineral analysis, radiation dosimetry and laser materials characterisation: This project will provide equipment with a vast capability to collect ultraviolet to mid-infrared fluorescence with high temporal measurement accuracy, and highly flexible excitation (spectral and temporal). This will enhance ....UV to mid-infrared fluorescence spectrometer for use in mineral analysis, radiation dosimetry, and laser materials characterisation. Ultraviolet to mid-infrared fluorescence spectrometer for use in mineral analysis, radiation dosimetry and laser materials characterisation: This project will provide equipment with a vast capability to collect ultraviolet to mid-infrared fluorescence with high temporal measurement accuracy, and highly flexible excitation (spectral and temporal). This will enhance active research into new glasses and laser crystals, probing of defect states resulting from ionising radiation absorption in environmental and medical dosimetry materials, investigation of novel fluorescence techniques for mineral identification, through to improving chemical detection capability (for example, detection of explosives). The instrument comprises modules that enable excitation in the ultraviolet, visible, and infrared from a tunable laser system, and high-efficiency collection and processing of fluorescence spectra.Read moreRead less