A novel platform-technology for long-term subcutaneous neurophysiology. This project aims to develop a novel miniature device for subcutaneous and tetherless brain sensing. It addresses the lack of a device solution for brain-sensing that combines ultra-long-term reliable sensing capability and small dimensions for minimally-invasive procedures. We achieve this through our novel electrode architecture that significantly enhances the quality and reliability of recorded brain signals. We introduce ....A novel platform-technology for long-term subcutaneous neurophysiology. This project aims to develop a novel miniature device for subcutaneous and tetherless brain sensing. It addresses the lack of a device solution for brain-sensing that combines ultra-long-term reliable sensing capability and small dimensions for minimally-invasive procedures. We achieve this through our novel electrode architecture that significantly enhances the quality and reliability of recorded brain signals. We introduce a platform technology designed for subscalp anatomy with future use in various brain-machine interfacing applications relying on reliable, long-term and easy-to-implant systems. This project's device manufacturing, training, and intellectual property are expected to strengthen Australia's position in bioelectronics.Read moreRead less
Towards a unified technology platform for sensing in liquids. Towards a unified technology platform for sensing in liquids. This project aims to use a new sensing platform for hydrocarbon monitoring in water to evolve optical on-chip position sensing of suspended micro-structures. Microelectromechanical systems dominate the world in sensing technology; they are common in smartphone, automotive, aerospace, and military applications. However, this multibillion dollar industry has failed to make ch ....Towards a unified technology platform for sensing in liquids. Towards a unified technology platform for sensing in liquids. This project aims to use a new sensing platform for hydrocarbon monitoring in water to evolve optical on-chip position sensing of suspended micro-structures. Microelectromechanical systems dominate the world in sensing technology; they are common in smartphone, automotive, aerospace, and military applications. However, this multibillion dollar industry has failed to make chem/bio sensing profitable, mostly due to the absence of a robust and compact read-out technology for sensing in liquids. This project is expected to lead to a unified parallel sensing platform of ultimate sensitivity delivering aqueous sensing for wide ranging applications and markets.Read moreRead less
Silicon-photonic devices harnessing new resonance phenomena. Silicon photonics is emerging as a billion dollar global technology industry and waveguide resonators are among the most crucial building blocks for silicon photonic systems. This project aims to introduce an entirely new class of optical waveguide resonator based on recently discovered unusual coupling behaviour in silicon photonics. The science underpinning this new effect will be investigated and experimentally verified and the myri ....Silicon-photonic devices harnessing new resonance phenomena. Silicon photonics is emerging as a billion dollar global technology industry and waveguide resonators are among the most crucial building blocks for silicon photonic systems. This project aims to introduce an entirely new class of optical waveguide resonator based on recently discovered unusual coupling behaviour in silicon photonics. The science underpinning this new effect will be investigated and experimentally verified and the myriad opportunities for novel device concepts will be explored. The compact resonant structures resulting from this project are expected to offer unprecedented filtering functionality while remaining compatible with silicon photonic mass manufacture, ensuring they can be easily utilised by the broader community.Read moreRead less
Implementation of cognitive radar techniques in resource limited radar systems. Cognitive radar technology enables a multiple functional radar system to be built on a single chip, to be of high efficiency and low cost. Waveform design and scheduling play a key role in such a system. This project will investigate and design waveforms and scheduling methods for building a real cognitive radar system in the extremely high frequency band.
Synthesis, characterisation, and applications of atomically thin layers of transition metal oxides and dichalcogenides. The project will explore the key fundamental properties of atomically-thin layers of functional materials made of transition metal oxides and dichalcogenides. By reducing the thickness of these materials to only a few atomic layers, the project will create novel electronic properties that are otherwise not exhibited. The aims are to understand layer-dependent changes to their p ....Synthesis, characterisation, and applications of atomically thin layers of transition metal oxides and dichalcogenides. The project will explore the key fundamental properties of atomically-thin layers of functional materials made of transition metal oxides and dichalcogenides. By reducing the thickness of these materials to only a few atomic layers, the project will create novel electronic properties that are otherwise not exhibited. The aims are to understand layer-dependent changes to their physical and chemical properties; to control and tune such properties by altering crystal structure and composition; and to investigate the effect of mixed-layer heterostructure configurations on these characteristics. The fundamental insights gained will serve as the driver for the next generation nanotechnology-enabled electronics and sensing systems.Read moreRead less
Photonic chip inertial movement sensors. This project aims to create a new class of optical inertial movement sensors using integrated photonic chip technology. By replacing optical fibre coils with compact waveguides, integrating light sources on-chip and by harnessing smart sensing approaches, we intend to reduce the required power from watts to milliwatts and reduce the dimensions from meters to centimetres. The expected project outcomes are sensors with military grade precision but with the ....Photonic chip inertial movement sensors. This project aims to create a new class of optical inertial movement sensors using integrated photonic chip technology. By replacing optical fibre coils with compact waveguides, integrating light sources on-chip and by harnessing smart sensing approaches, we intend to reduce the required power from watts to milliwatts and reduce the dimensions from meters to centimetres. The expected project outcomes are sensors with military grade precision but with the size, cost and manufacturability of consumer electronics. This technology will fill a strategic gap in the movement sensor market enabling applications ranging from robotic infrastructure monitoring, manufacture and surgery to guiding satellites and other space craft.Read moreRead less
Multilayer thin film memristors: designing interfaces and defect states in perovskites for nanoscale multi-state memories. This project will explore memristive devices, a frontier electronic memory technology, where the memory element's behaviour depends on its prior electronic experiences. This project will attempt to understand the processes that govern the storage and recall of information, to realise functional materials and interfaces that maximise memristive performance.
Discovery Early Career Researcher Award - Grant ID: DE160100023
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
Flexible transparent oxides – the future of electronics is clear. This project aims to support the development of flexible electronic devices incorporating the functional properties of oxide thin films. Oxide thin films require high processing temperatures, which are incompatible with flexible substrates. This project seeks to provide a solution by using a novel transfer process that allows oxides to be combined with flexible polymer substrates. Applications in sensing under the influence of hea ....Flexible transparent oxides – the future of electronics is clear. This project aims to support the development of flexible electronic devices incorporating the functional properties of oxide thin films. Oxide thin films require high processing temperatures, which are incompatible with flexible substrates. This project seeks to provide a solution by using a novel transfer process that allows oxides to be combined with flexible polymer substrates. Applications in sensing under the influence of heat, gas, and light will be studied. This project will potentially create devices that can be conformally applied to surfaces or worn on a person to act as low-cost sensors for toxic gases or ultraviolet radiation.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150100909
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Metal oxide memristors: Switching phenomena in van der Waals nanostructures. This project aims to integrate two recently researched phenomena: memristors (resistive memory) and planar materials. It aims to adopt atomically thin, planar materials for memristors enabling the realisation of high performance resistive memory devices. The physical and environmental effects that govern the memristive properties, which are of utmost importance in understanding resistive memory nature, will be investiga ....Metal oxide memristors: Switching phenomena in van der Waals nanostructures. This project aims to integrate two recently researched phenomena: memristors (resistive memory) and planar materials. It aims to adopt atomically thin, planar materials for memristors enabling the realisation of high performance resistive memory devices. The physical and environmental effects that govern the memristive properties, which are of utmost importance in understanding resistive memory nature, will be investigated. While generating breakthrough knowledge, the key outcomes of this project will lay the foundation for a novel class of memory devices based on planar van der Waals nanostructures. Such a breakthrough will contribute to the realisation of sustainable memristor technology.Read moreRead less
CMOS compatible nonlinear photonic integrated circuits. Bandwidth and energy demands of telecommunications networks are rapidly reaching a crisis point technologically, economically and from a sustainability viewpoint. At the same time, on-chip interconnects for silicon integrated circuits are also reaching a bottleneck. This project aims to combine the expertise of eight leading international groups to pioneer nonlinear photonic integrated circuits compatible with silicon technology (Complement ....CMOS compatible nonlinear photonic integrated circuits. Bandwidth and energy demands of telecommunications networks are rapidly reaching a crisis point technologically, economically and from a sustainability viewpoint. At the same time, on-chip interconnects for silicon integrated circuits are also reaching a bottleneck. This project aims to combine the expertise of eight leading international groups to pioneer nonlinear photonic integrated circuits compatible with silicon technology (Complementary Metal Oxide Semiconductor technology, or CMOS) to achieve new capabilities on a chip for signal generation, processing and measurement for telecommunications, computers, and fundamental science. These platforms are expected to allow the integration of electronics with photonics and to be faster, cheaper, smaller, and more energy efficient than current technology.Read moreRead less