Electro-triggered solidification of supercooled fusible alloys. Stiffness is typically considered a static property of a material. Traditionally, once the stiffness is specified, it is not expected to change during operation. This project aims to turn a problem (i.e., supercooling) into an opportunity for creating fusible alloy composites with electroprogrammable stiffness that can outperform state-of-the-art materials by offering all desirable properties. Expected outcomes are the rapid, contin ....Electro-triggered solidification of supercooled fusible alloys. Stiffness is typically considered a static property of a material. Traditionally, once the stiffness is specified, it is not expected to change during operation. This project aims to turn a problem (i.e., supercooling) into an opportunity for creating fusible alloy composites with electroprogrammable stiffness that can outperform state-of-the-art materials by offering all desirable properties. Expected outcomes are the rapid, continuous, large, and reversible change in stiffness of the composite through electrical control. This project will provide significant benefits by enabling an increasing number of emerging applications in areas such as robotics, manufacturing, and consumer wearables that require materials with tuneable stiffness.Read moreRead less
Thermal engineering in semiconductor heterojunction for space transducers . Microelectromechanical system (MEMS) transducers, including sensors and actuators, are essential for space applications. However, MEMS transducers have not yet provided compelling performance for the space industry as they typically experience degradation of performance when subjected to elevated temperature and radiation. This research aims to develop an innovative transducer technology that uses a temperature gradient ....Thermal engineering in semiconductor heterojunction for space transducers . Microelectromechanical system (MEMS) transducers, including sensors and actuators, are essential for space applications. However, MEMS transducers have not yet provided compelling performance for the space industry as they typically experience degradation of performance when subjected to elevated temperature and radiation. This research aims to develop an innovative transducer technology that uses a temperature gradient to enhance performance and a radiation-hard material to ensure reliability and longevity. Expected outcomes include improved understanding of transducer performance under temperature gradient, appropriate material selection, and design recommendations for high-performance transducers with applications in space and defence.Read moreRead less
Liquid metal composite tactile sensor. Tactile sensing electronic skin is a key enabling technology for smart robotic grippers and neuroprosthetics. However, traditional electronic skin is still underdeveloped in sensing of slip and force direction. Therefore, this project aims to imitate human skin structure to develop a highly sensitive liquid metal-enabled electronic skin that can achieve high-performance multiple tactile sensation capabilities, including normal-tangential force decoupling a ....Liquid metal composite tactile sensor. Tactile sensing electronic skin is a key enabling technology for smart robotic grippers and neuroprosthetics. However, traditional electronic skin is still underdeveloped in sensing of slip and force direction. Therefore, this project aims to imitate human skin structure to develop a highly sensitive liquid metal-enabled electronic skin that can achieve high-performance multiple tactile sensation capabilities, including normal-tangential force decoupling and slip detection. The expected outcome will enable future manipulator and prosthetics to detect complex forces for precision manipulation, which will provide benefits to advanced manufacturing and bring significant economic and social benefits.Read moreRead less
Micro-electromechanical technology for harnessing terahertz waves. This project proposes novel low-cost miniature devices for spectral, spatial and temporal manipulation of terahertz waves realised using a unified platform based on a single material and fabrication technology sufficiently generic to span the entire very broad terahertz band. It inherently overcomes the most hindering issue of current terahertz instruments relating to the limited span of the spectrum each tool can cover and the h ....Micro-electromechanical technology for harnessing terahertz waves. This project proposes novel low-cost miniature devices for spectral, spatial and temporal manipulation of terahertz waves realised using a unified platform based on a single material and fabrication technology sufficiently generic to span the entire very broad terahertz band. It inherently overcomes the most hindering issue of current terahertz instruments relating to the limited span of the spectrum each tool can cover and the high costs associated with increasing this span; removing the need for making spectral band compromises in the design of future tools. The intended outcome is a platform for terahertz spectroscopic imaging, target recognition, detection of chemical composition of objects, and future high-bandwidth communications.Read moreRead less
Engineering nanomembranes for Long-term Implanted Flexible Electronics. This project aims to investigate the key technologies of inorganic semiconductor nanomembranes for long-lived bio-integrated electronics. Taking advantage of the well-established silicon carbide (SiC) synthesis and fabrication technology, the project expects to elucidate a new understanding of the SiC-on-polymer platform, establishing a foundational guideline for the development of chemically inert and mechanically flexible ....Engineering nanomembranes for Long-term Implanted Flexible Electronics. This project aims to investigate the key technologies of inorganic semiconductor nanomembranes for long-lived bio-integrated electronics. Taking advantage of the well-established silicon carbide (SiC) synthesis and fabrication technology, the project expects to elucidate a new understanding of the SiC-on-polymer platform, establishing a foundational guideline for the development of chemically inert and mechanically flexible devices. These findings will offer innovative solutions for daunting challenges in bio-integrated electronics, leveraging their safety, reliability, and long-term performance. The project expects to offer Australia cutting edge technologies and an impact profile in the fast-growing flexible bio-electronics market.Read moreRead less
Parallel Lines: Ultra-dense optical systems for extreme data-rates. The project aims to explore methods to significantly expand global internet data rates, by using emerging ultra-dense optical technologies. The project plans to discover how novel existing and emerging tiny photonic chip devices may enable the use of new, unused optical spectral bands, and then enable 1000s of channels to be supported by exploiting newly available parallelism in both wavelength and space. Success in the project ....Parallel Lines: Ultra-dense optical systems for extreme data-rates. The project aims to explore methods to significantly expand global internet data rates, by using emerging ultra-dense optical technologies. The project plans to discover how novel existing and emerging tiny photonic chip devices may enable the use of new, unused optical spectral bands, and then enable 1000s of channels to be supported by exploiting newly available parallelism in both wavelength and space. Success in the project aims may enable speeds of up to 100 times greater than achievable today, in a variety of fibre optic systems. Connectivity is key to our society, so benefits may arise in both future-proofing key Australian data infrastructure, and in providing a roadmap to support exponential capacity growth over the coming decades.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100382
Funder
Australian Research Council
Funding Amount
$449,154.00
Summary
Charge and Energy Transfer Processes at Inorganic-Organic Interfaces . The integration of functional molecular materials with inorganic systems remains an outstanding hurdle to achieve durable, highly efficient optoelectronic devices. This project aims to develop and understand this new class of devices, with a focus on directional energy transfer processes across hybrid interfaces. This project expects to generate new knowledge in photovoltaics (PV) and for organic light emitting diodes (OLEDs) ....Charge and Energy Transfer Processes at Inorganic-Organic Interfaces . The integration of functional molecular materials with inorganic systems remains an outstanding hurdle to achieve durable, highly efficient optoelectronic devices. This project aims to develop and understand this new class of devices, with a focus on directional energy transfer processes across hybrid interfaces. This project expects to generate new knowledge in photovoltaics (PV) and for organic light emitting diodes (OLEDs) by studying triplet transfer in two model systems. The first will be a step towards the development of advanced PV devices using down-conversion to push solar cells beyond the efficiency barrier. The second will demonstrate inorganic-organic solid state up-conversion for next generation OLEDs with improved stability.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100045
Funder
Australian Research Council
Funding Amount
$410,000.00
Summary
Cryogenic microwave characterization facility for quantum technologies. This project will establish a multi-user, fast-turn-around cryogenic characterization facility for microwave superconducting quantum technologies that are critical components for quantum computer, networks and sensor systems. This facility will lead to a significant improvement in research efficiency, allowing for rapid optimization of devices and components prior to integration into a larger quantum system. Expected outcome ....Cryogenic microwave characterization facility for quantum technologies. This project will establish a multi-user, fast-turn-around cryogenic characterization facility for microwave superconducting quantum technologies that are critical components for quantum computer, networks and sensor systems. This facility will lead to a significant improvement in research efficiency, allowing for rapid optimization of devices and components prior to integration into a larger quantum system. Expected outcomes include the creation of new intellectual property, enhanced engagement with industry, and will further boost Australia's efforts to build a commercially scalable quantum computer. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100408
Funder
Australian Research Council
Funding Amount
$446,411.00
Summary
Advancing bioelectronics with silicon carbide on microfluidics. Flexible bioelectronics is an emerging technology for real-time monitoring of vital signals on skin and in the body. Microfluidics is a technology for fluid handling in microscale. This project aims to develop the first platform technology with both flexible bioelectronics and microfluidics for enhanced sensing, thermal management and actuation. The project is expected to establish new fundamental knowledge in sensitivity boosting m ....Advancing bioelectronics with silicon carbide on microfluidics. Flexible bioelectronics is an emerging technology for real-time monitoring of vital signals on skin and in the body. Microfluidics is a technology for fluid handling in microscale. This project aims to develop the first platform technology with both flexible bioelectronics and microfluidics for enhanced sensing, thermal management and actuation. The project is expected to establish new fundamental knowledge in sensitivity boosting mechanisms with nano-thin semiconducting films, practical prototypes for long-lasting bioelectronics with integrated microfluidics and their large-scale manufacturing processes. Outcomes include step changes in designing innovative wearable and implantable devices and their massive commercialisation opportunities.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100587
Funder
Australian Research Council
Funding Amount
$443,347.00
Summary
A quantum telescope for extremely high-resolution imaging. This project will combine world-leading Australian signal stabilisation technology with recent developments in quantum sensors to demonstrate the world’s first quantum telescope. This project expects to demonstrate that quantum detectors can feasibly link optical telescopes, separated by hundreds of kilometres, to achieve extremely high-resolution imaging. Expected outcomes are the development of technologies that will enable imaging wit ....A quantum telescope for extremely high-resolution imaging. This project will combine world-leading Australian signal stabilisation technology with recent developments in quantum sensors to demonstrate the world’s first quantum telescope. This project expects to demonstrate that quantum detectors can feasibly link optical telescopes, separated by hundreds of kilometres, to achieve extremely high-resolution imaging. Expected outcomes are the development of technologies that will enable imaging with resolution more than 20 times better than any existing telescope. This will provide significant benefits for astronomy, space situational awareness, and defence.Read moreRead less