Auditory perception in neural electronics. This project aims to develop a practical alternative to conventional electronic design. Faster and more powerful devices have resulted from placing ever more transistors on a computer chip, but this is reaching its physical limits. This project will develop a new way of designing smart electronic devices by taking inspiration from signal processing in biological brains, and applying it to the processing of audio signals. Expected outcomes are a device t ....Auditory perception in neural electronics. This project aims to develop a practical alternative to conventional electronic design. Faster and more powerful devices have resulted from placing ever more transistors on a computer chip, but this is reaching its physical limits. This project will develop a new way of designing smart electronic devices by taking inspiration from signal processing in biological brains, and applying it to the processing of audio signals. Expected outcomes are a device that recognises sounds, without needing remote computers to do the processing. These techniques can be applied to other senses, such as vision, advancing machine perception and enabling smarter devices.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101032
Funder
Australian Research Council
Funding Amount
$345,000.00
Summary
Electronics of the future: self-powering wireless circuit design. The aim of this project is to build a foundation for ultra-low-power wireless circuit design using technologies other than silicon. Scaling of transistors in silicon has been pushed to its limit and is of marginal benefit for low-power wireless circuit design. This project aims to address these limits by developing energy-efficient technology for wireless applications. The intended outcome of this project will be a self-powered, h ....Electronics of the future: self-powering wireless circuit design. The aim of this project is to build a foundation for ultra-low-power wireless circuit design using technologies other than silicon. Scaling of transistors in silicon has been pushed to its limit and is of marginal benefit for low-power wireless circuit design. This project aims to address these limits by developing energy-efficient technology for wireless applications. The intended outcome of this project will be a self-powered, high data rate receiver that will be critical in 5th-generation wireless systems. This could be used for a range of innovative wireless applications, for example in health care and environmental monitoring.Read moreRead less
Autonomous body sensors in humans: investigating new bio-sensing techniques with self-power generation. Using advanced integrated electronic and mechanical systems, it is now possible to design small biomedical sensors that can be inserted into the body to take biological measurements. This project introduces a new kind of bio-sensors with self-energy generation capability and reduces the need for periodic battery replacement. New wireless and circuit techniques are investigated to reduce power ....Autonomous body sensors in humans: investigating new bio-sensing techniques with self-power generation. Using advanced integrated electronic and mechanical systems, it is now possible to design small biomedical sensors that can be inserted into the body to take biological measurements. This project introduces a new kind of bio-sensors with self-energy generation capability and reduces the need for periodic battery replacement. New wireless and circuit techniques are investigated to reduce power consumption and physical dimensions, while providing a better performance and a safer wireless link. The project aims to deliver high level of comfort, better mobility and better patient care.Read moreRead less
Foundations for Physically Unclonable nano-Security on Silicon. This project aims to develop an on-chip physical unclonable function (PUF) based on recent progress in nanotechnology to generate unprecedented number of unique signatures. This is significant because these signatures can be used for preventing fraud and counterfeiting, protecting sensitive data and securing communications. PUFs will play an extremely vital role in future security systems. The PUF in the proposed project will be sim ....Foundations for Physically Unclonable nano-Security on Silicon. This project aims to develop an on-chip physical unclonable function (PUF) based on recent progress in nanotechnology to generate unprecedented number of unique signatures. This is significant because these signatures can be used for preventing fraud and counterfeiting, protecting sensitive data and securing communications. PUFs will play an extremely vital role in future security systems. The PUF in the proposed project will be simple, fast, tiny, energy efficient and highly secure as a result of the abundant nano-fabrication variations. The outcome of this project will be a prototype of a super high secure nanoelectronic-based PUF that will be tested to evaluate the technology and its security against malicious attacks.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100126
Funder
Australian Research Council
Funding Amount
$527,638.00
Summary
Advanced Maskless Photolitography for Western Australia. This project aims to close an existing gap in micro- & nano-fabrication in Western Australia and provide access to advanced maskless photolithography in support of Australian research flagships of international excellence which include advanced infrared and quantum technologies, semiconductor optoelectronics, chemical engineering, microelectromechanical systems, as well as dark matter and gravitational wave discovery. Notably, the new capa ....Advanced Maskless Photolitography for Western Australia. This project aims to close an existing gap in micro- & nano-fabrication in Western Australia and provide access to advanced maskless photolithography in support of Australian research flagships of international excellence which include advanced infrared and quantum technologies, semiconductor optoelectronics, chemical engineering, microelectromechanical systems, as well as dark matter and gravitational wave discovery. Notably, the new capability is of utmost importance for five distinct ARC Centres in multidisciplinary areas and will be available to all researchers via the WA Node of Australian National Fabrication Facility in support of high impact scientific research and to maintain strong engagement with industry and Australian economy.Read moreRead less
Intermetallic compounds for high reliability electronic interconnections. The aim of the proposal is to develop an entirely new way of joining functional elements of circuit boards using tailored intermetallic joints that replace traditional solders. The outcome will be that electronic devices, from smart phones to smart grids and electric vehicles, will become more reliable and less susceptible to cracking and circuit failure. Electronics will last longer and less E-waste will be generated. Thi ....Intermetallic compounds for high reliability electronic interconnections. The aim of the proposal is to develop an entirely new way of joining functional elements of circuit boards using tailored intermetallic joints that replace traditional solders. The outcome will be that electronic devices, from smart phones to smart grids and electric vehicles, will become more reliable and less susceptible to cracking and circuit failure. Electronics will last longer and less E-waste will be generated. This would revolutionise electronics manufacturing. The project has a high probability of achieving this breakthrough based on unique, world-class expertise in intermetallic compounds and characterisation that has already been established by the international network of Investigators.Read moreRead less
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
Diamond glass: An all-carbon technology for neural networks and biosensing. This project aims to use plasma deposition to synthesise diamond glass with the highest purity and the most diamond-like character so that it meets the strict requirements for emerging device applications. The extreme properties of diamond glass arise from the diamond-like bonding of the majority of its atoms. This amorphous, wide bandgap semiconductor is also the hardest known glass. The maximum diamond-like content pos ....Diamond glass: An all-carbon technology for neural networks and biosensing. This project aims to use plasma deposition to synthesise diamond glass with the highest purity and the most diamond-like character so that it meets the strict requirements for emerging device applications. The extreme properties of diamond glass arise from the diamond-like bonding of the majority of its atoms. This amorphous, wide bandgap semiconductor is also the hardest known glass. The maximum diamond-like content possible in diamond glass coatings is unknown, so determining its ultimate performance is difficult. Expected applications include medical diagnostics, non-volatile memories and programmable chips.Read moreRead less
Molecular Alignments in Organic Semiconductors. The proposed research project is focus on molecular alignments in solution-based organic semiconductors, which is at the frontier of research in the interdisciplinary field of plastic electronics. Molecular ordering has tremendous potential in enhancing both electrical and optical properties and opens up a way to realise new class of molecular electronic and optoelectronic devices. Significant learning from these devices can be applied to practical ....Molecular Alignments in Organic Semiconductors. The proposed research project is focus on molecular alignments in solution-based organic semiconductors, which is at the frontier of research in the interdisciplinary field of plastic electronics. Molecular ordering has tremendous potential in enhancing both electrical and optical properties and opens up a way to realise new class of molecular electronic and optoelectronic devices. Significant learning from these devices can be applied to practical high performance devices to be extremely cheap, recyclable, and mechanical flexible. Read moreRead less