Digitally Assisted Power Amplifier Design with Enhanced Energy Efficiency. The project aims to advance design techniques for power amplifiers operating in the recently allocated spectrum for 5G New Radio, from approximately 24 GHz to 52 GHz. The intended outcome is a compact and high efficiency transmitter using digitally assisted power amplifier design techniques in low-cost Complementary Metal–Oxide–Semiconductor (CMOS) technology. Such innovation will have significant impacts on our daily lif ....Digitally Assisted Power Amplifier Design with Enhanced Energy Efficiency. The project aims to advance design techniques for power amplifiers operating in the recently allocated spectrum for 5G New Radio, from approximately 24 GHz to 52 GHz. The intended outcome is a compact and high efficiency transmitter using digitally assisted power amplifier design techniques in low-cost Complementary Metal–Oxide–Semiconductor (CMOS) technology. Such innovation will have significant impacts on our daily life, as it will build the hardware foundation for the next generation of wireless systems. Consequently, various emerging applications such as virtual/augmented reality will be supported, maintaining national leadership in the development of wireless technology, and providing economic benefits for Australian industries.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100010
Funder
Australian Research Council
Funding Amount
$928,291.00
Summary
Single-molecule Manipulation and Interaction Facility (SMIF). This LIEF project aims to establish Australia's first Single-molecule Manipulation and Interaction Facility (SMIF), providing multidisciplinary researchers with a platform to explore cellular processes and reveal molecular mechanisms at the nanoscale. The SMIF facility incorporates cutting-edge technologies for bio-manipulation, real-time visualisation, and characterisation of single-molecule interactions, overcoming the technical com ....Single-molecule Manipulation and Interaction Facility (SMIF). This LIEF project aims to establish Australia's first Single-molecule Manipulation and Interaction Facility (SMIF), providing multidisciplinary researchers with a platform to explore cellular processes and reveal molecular mechanisms at the nanoscale. The SMIF facility incorporates cutting-edge technologies for bio-manipulation, real-time visualisation, and characterisation of single-molecule interactions, overcoming the technical complexity of traditional tools requiring highly specialised personnel. By offering accessible, easy-to-use advanced systems, this project will significantly boost scientific discovery across physics, chemistry, and biology, fostering collaboration and innovation to better understand life at the molecular level.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240101298
Funder
Australian Research Council
Funding Amount
$415,727.00
Summary
Strategies enabling stable perovskite PV devices with efficiency beyond 25%. This project aims to develop technologies enabling stable perovskite photovoltaic (PV) devices with efficiency beyond 25%. The project is built upon my up-to-date achievements on efficiency and patented technologies on stability. The key concept is to lay single-crystalline-featured electron-transport-layer as foundation, followed by superior and neat perovskite light harvesting material through backbone modulation, cr ....Strategies enabling stable perovskite PV devices with efficiency beyond 25%. This project aims to develop technologies enabling stable perovskite photovoltaic (PV) devices with efficiency beyond 25%. The project is built upon my up-to-date achievements on efficiency and patented technologies on stability. The key concept is to lay single-crystalline-featured electron-transport-layer as foundation, followed by superior and neat perovskite light harvesting material through backbone modulation, crystal-facets management and surface-impurity removal. The outcomes are expected to deliver intellectual property academically and commercially, including new knowledge in addressing challenges toward efficient and stable perovskite PV devices and the associated patents for next-stage commercialization.Read moreRead less
Wireless Integrated Circuits for the Era of 6G: System-in-a-Package. The aim of this project is to build a hardware foundation for future wireless integrated circuits, using a combination of silicon and compound semiconductor technologies. The project will generate knowledge for circuit design and system integration to pivot towards the engineering of emerging 6G technology. Expected outcomes include a transceiver-in-package using multiple semiconductor technologies and the development of sovere ....Wireless Integrated Circuits for the Era of 6G: System-in-a-Package. The aim of this project is to build a hardware foundation for future wireless integrated circuits, using a combination of silicon and compound semiconductor technologies. The project will generate knowledge for circuit design and system integration to pivot towards the engineering of emerging 6G technology. Expected outcomes include a transceiver-in-package using multiple semiconductor technologies and the development of sovereign design capabilities. The results will constitute an important step towards implementing 6G. Benefits for Australia include the development of early career workers, generation of intellectual property, and securing social and economic benefits for Australians through application of this next-generation technology.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101711
Funder
Australian Research Council
Funding Amount
$452,154.00
Summary
Printed Infrared Quantum Dot Photodetectors and Large-scale Image Sensors . Detectors operating in shortwave infrared region are critical in civil and military applications. This project aims to demonstrate revolutionary low-cost and high performing shorwave infrared lead sulfide quantum dot photodetectors and large-scale image sensors with compatible structures for the potential applications on complementary metal–oxide–semiconductor readout integrated circuits through fully printing. Expected ....Printed Infrared Quantum Dot Photodetectors and Large-scale Image Sensors . Detectors operating in shortwave infrared region are critical in civil and military applications. This project aims to demonstrate revolutionary low-cost and high performing shorwave infrared lead sulfide quantum dot photodetectors and large-scale image sensors with compatible structures for the potential applications on complementary metal–oxide–semiconductor readout integrated circuits through fully printing. Expected outcomes of this project included the new understandings of surface passivation, interfacial engineering and device design. The shortwave technologies developed in this project will be highly prospective for commercialization in the near future, which would bring Australia’s shortwave technologies to a new stage. Read moreRead less
Next Generation Terahertz Materials. We will investigate novel tuneable terahertz (THz) metamaterials, based on the exploitation of phase change materials. Tunable metamaterial-based terahertz devices, such as modulators and filters, will potentially generate significant downstream IP for short-path wireless applications. This fills a critical need to meet the increasing demand for greater bandwidth. Elucidation of the fundamental science underlying the interaction between terahertz signals and ....Next Generation Terahertz Materials. We will investigate novel tuneable terahertz (THz) metamaterials, based on the exploitation of phase change materials. Tunable metamaterial-based terahertz devices, such as modulators and filters, will potentially generate significant downstream IP for short-path wireless applications. This fills a critical need to meet the increasing demand for greater bandwidth. Elucidation of the fundamental science underlying the interaction between terahertz signals and phase-change materials will enable tuneable metamaterials. A major leap will be devices that can steer and modulate terahertz signals with unprecedented agility and compactness; enabling future high-bandwidth desktop data transfer.Read moreRead less