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
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
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.
Rainbows on demand: coherent comb sources on a photonic chip. This project aims to create photonic circuit technologies that will generate hundreds of coherent laser lines from a single chip. The emerging industrially scalable silicon nitride on thin-film lithium niobate platform will be advanced to create resonant modulators and nonlinear waveguides with unprecedented efficiency and innovative monitoring and control techniques. When combined, these components will enable highly flexible and rob ....Rainbows on demand: coherent comb sources on a photonic chip. This project aims to create photonic circuit technologies that will generate hundreds of coherent laser lines from a single chip. The emerging industrially scalable silicon nitride on thin-film lithium niobate platform will be advanced to create resonant modulators and nonlinear waveguides with unprecedented efficiency and innovative monitoring and control techniques. When combined, these components will enable highly flexible and robust systems for generating a comb of coherent laser lines. These photonic chip comb sources will be inexpensive, compact and energy efficient with transformative impact in spectroscopy, microscopy, precision measurement, quantum computing and ultra-fast optical fibre communications.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
Dynamic substrates for surface-enhanced Raman scattering: piezoelectric actuated nanotextures with phase-locked signal processing. Surface-enhanced Raman scattering shows great promise for sensitive detection of a wide range of chemical and biological compounds. Novel electronic devices will be produced to actively tune the nanometre scale structures that generate the scattering signal, resulting in an improved fundamental understanding and control of the effect.
Electronically controlled phased array antenna for universal Ultra-High-Frequency (UHF) Radio-Frequency Identification (RFID) applications. RFID may potentially replace barcodes allowing automated identification of individual items at multiple points in supply and distribution chains. A smart antenna engineered RFID reader improves efficacy in a host of applications such as logistics and security surveillance and tremendously benefits Australian economy as a key player in the field.