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Nanowire quantum well infrared photodetectors. This project aims to demonstrate semiconductor nanowire based quantum well infrared (IR) photodetectors for applications in chemical analysis, remote sensing, thermal imaging, environmental monitoring, space ranging and communications. By utilising one-dimensional nanowire detector architecture, the project expects that improved sensitivity, functionality and reduced cost can be achieved surpassing the performance of current IR technologies. This pr ....Nanowire quantum well infrared photodetectors. This project aims to demonstrate semiconductor nanowire based quantum well infrared (IR) photodetectors for applications in chemical analysis, remote sensing, thermal imaging, environmental monitoring, space ranging and communications. By utilising one-dimensional nanowire detector architecture, the project expects that improved sensitivity, functionality and reduced cost can be achieved surpassing the performance of current IR technologies. This project will pave the way for a new research and development platform for next generation large scale, low cost, high performance IR systems with commercialisation opportunities accessible to both high-end defence sectors and broader civilian industries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100413
Funder
Australian Research Council
Funding Amount
$384,000.00
Summary
Hybrid nanowire-nanoantenna infrared photodetectors. This project aims to demonstrate room temperature hybrid nanowire-nanoantenna infrared photodetectors by integrating plasmonic nanoantennas on semiconductor nanowire arrays. It is expected that such novel device architectures will not only bring enhanced performance in responsivity, detectivity, and photoresponse bandwidth, but also additional functionalities such as selective wavelength and tunable polarisation, which may significantly outper ....Hybrid nanowire-nanoantenna infrared photodetectors. This project aims to demonstrate room temperature hybrid nanowire-nanoantenna infrared photodetectors by integrating plasmonic nanoantennas on semiconductor nanowire arrays. It is expected that such novel device architectures will not only bring enhanced performance in responsivity, detectivity, and photoresponse bandwidth, but also additional functionalities such as selective wavelength and tunable polarisation, which may significantly outperform current infrared technology. The outcomes will provide a new device platform for next-generation, large-scale, reduced-cost, high-performance imaging systems in self-driving navigation, object identification, spectroscopy, and other high-end defence and civilian applications.Read moreRead less
Ultrathin III-V Solar Cells via Crack-Assisted Layer Exfoliation. III-V semiconductors are excellent photovoltaic materials with highest demonstrated solar-to-electricity conversion efficiencies, but find limited usage in terrestrial applications due to high material and fabrication costs. This project aims to improve the cost-effectiveness of III-V solar cells by developing ultrathin III-V semiconductors via crack-assisted layer transfer approach and epitaxy-free fabrication via heterojunction ....Ultrathin III-V Solar Cells via Crack-Assisted Layer Exfoliation. III-V semiconductors are excellent photovoltaic materials with highest demonstrated solar-to-electricity conversion efficiencies, but find limited usage in terrestrial applications due to high material and fabrication costs. This project aims to improve the cost-effectiveness of III-V solar cells by developing ultrathin III-V semiconductors via crack-assisted layer transfer approach and epitaxy-free fabrication via heterojunction architectures, paving the way for cost-effective, high-efficiency, flexible solar cells. The expected outcomes include a disruptive technology for integrated photovoltaics, novel contact and passivation materials, as well as new knowledge generated in materials science and optoelectronics disciplines.Read moreRead less
Efficient, durable and green chalcopyrite solar powered building steel. This project aims to develop a long-life, stable, high-performance, and green chalcopyrite solar powered building steel, which is expected to offer a shapable truly green building integrated photovoltaic (BIPV) product for building deployment. This will be realized by synergising multidiscipline expertise, integrating established technologies of steel surface treatment, steel and solar cell integration and shaping, high-effi ....Efficient, durable and green chalcopyrite solar powered building steel. This project aims to develop a long-life, stable, high-performance, and green chalcopyrite solar powered building steel, which is expected to offer a shapable truly green building integrated photovoltaic (BIPV) product for building deployment. This will be realized by synergising multidiscipline expertise, integrating established technologies of steel surface treatment, steel and solar cell integration and shaping, high-efficiency chalcopyrite, identified strategies for tackling its durability and toxicity, and advanced macro-to-micro characterizations. The project completion will accelerate the transition to the zero-emission building, establish Australia's excellence in green steel for BIPV, and access a share in the soaring BIPV market.Read moreRead less
Nanowire infrared avalanche photodetectors towards single photon detection. This project aims to demonstrate semiconductor nanowire based infrared avalanche photodetectors (APDs) with ultra-high sensitivity towards single photon detection. By employing the advantages of their unique one-dimensional nanoscale geometry, the nanowire APDs can be engineered to different device architectures to achieve performance superior to their conventional counterparts. It is expected that this project will mak ....Nanowire infrared avalanche photodetectors towards single photon detection. This project aims to demonstrate semiconductor nanowire based infrared avalanche photodetectors (APDs) with ultra-high sensitivity towards single photon detection. By employing the advantages of their unique one-dimensional nanoscale geometry, the nanowire APDs can be engineered to different device architectures to achieve performance superior to their conventional counterparts. It is expected that this project will make significant contributions to the development of next generation high performance, fast speed, small size and low cost infrared photodetector technology platform enabling numerous emerging fields in modern transportation, communication, quantum computation and information processing to revolutionise our life and society.Read moreRead less
III-V semiconductor nanowire solar cells without p-n junctions. This project proposes a new class of nanowire solar cells that do not rely on conventional electrical (p-n) junction for photo-generated charge carrier separation. Instead the band structure of the semiconductors is engineered to form a misalignment which leads to the spatial separation of carriers. This approach is expected to fundamentally change the design of solar cells, eliminating the technologically challenging need for formi ....III-V semiconductor nanowire solar cells without p-n junctions. This project proposes a new class of nanowire solar cells that do not rely on conventional electrical (p-n) junction for photo-generated charge carrier separation. Instead the band structure of the semiconductors is engineered to form a misalignment which leads to the spatial separation of carriers. This approach is expected to fundamentally change the design of solar cells, eliminating the technologically challenging need for forming good electrical junctions, while retaining all advantages inherent to III-V semiconductor nanowire solar cells. More importantly, the device concept proposed is expected to have implications for a wider class of solar cells based on exotic/novel materials or nanostructures where achieving both n- and p-doping may be challenging.Read moreRead less
Towards high performance compound semiconductor nanowire array solar cells. Semiconductor nanowires have great potential for photovoltaic applications due to their unique structural, electrical and optical properties. This project aims to establish a new research program to integrate highly sophisticated theoretical modelling, material growth and nanofabrication capabilities to develop high performance III-V compound semiconductor nanowire array solar cells. New concepts, strategies and technolo ....Towards high performance compound semiconductor nanowire array solar cells. Semiconductor nanowires have great potential for photovoltaic applications due to their unique structural, electrical and optical properties. This project aims to establish a new research program to integrate highly sophisticated theoretical modelling, material growth and nanofabrication capabilities to develop high performance III-V compound semiconductor nanowire array solar cells. New concepts, strategies and technologies developed by this project will not only advance the fundamental understanding of many intriguing physics in nanowire materials and devices, but also pave the way towards high efficiency photovoltaics to address the world’s energy-related issues. Read moreRead less
Nitride-based Compound Semiconductors for Solar Water Splitting. Global warming warrants urgent investment in clean and sustainable energy generation. This project aims to investigate the use of nitride semiconductors, a commonly used material for LEDs, and solar energy to generate hydrogen by splitting water molecules. These semiconductors have excellent light absorption efficiency and can be designed to better match the solar spectrum. The project will explore the underlying mechanism of light ....Nitride-based Compound Semiconductors for Solar Water Splitting. Global warming warrants urgent investment in clean and sustainable energy generation. This project aims to investigate the use of nitride semiconductors, a commonly used material for LEDs, and solar energy to generate hydrogen by splitting water molecules. These semiconductors have excellent light absorption efficiency and can be designed to better match the solar spectrum. The project will explore the underlying mechanism of light interaction with the semiconductor through band bending and surface engineering, and determine how this interaction affects the dissociation of water molecules. The concepts demonstrated in the project are expected to pave the way for further development of this technology for future applications. Read moreRead less
A fundamental study of electronic transport in advanced semiconductor nanostructures. The principal aim of this project is to attract and retain very high calibre early career researchers by providing them with the best-available infrastructure and research environment, combined with world-class supervision and mentoring. The project brings together an outstanding team of international collaborators, who will work with the early career researchers to ensure that they are trained and mentored at ....A fundamental study of electronic transport in advanced semiconductor nanostructures. The principal aim of this project is to attract and retain very high calibre early career researchers by providing them with the best-available infrastructure and research environment, combined with world-class supervision and mentoring. The project brings together an outstanding team of international collaborators, who will work with the early career researchers to ensure that they are trained and mentored at an international level. The new science, novel characterisation methods, and theoretical models that are outcomes of this project will provide new opportunities and expertise to advance the strategic defence and national security interests of Australia, and the emerging Australian semiconductor device and solar cell industry. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100159
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
National facility for biased target deposition of alloyed nanolayers. This facility will enhance Australia's strengths and capabilities in fabricating structures, with applications in multiple research fields including opto-magneto-electronics, next generation lithium ion batteries and energy nanogenerators. It will enhance Australia's research profile as a leader in nanotechnology.