Miniaturised Adiabatic Light Processing Devices. The project will develop, model and analyse a range of miniaturised light-processing devices for optical communications applications that rely soley on their geometrical design for their optical functionality. Such devices are less complex than devices that rely on other physical phenomena for their operation, such as interference, resonance or grating phenomena. They have potential application to a wide range of applications including optical tel ....Miniaturised Adiabatic Light Processing Devices. The project will develop, model and analyse a range of miniaturised light-processing devices for optical communications applications that rely soley on their geometrical design for their optical functionality. Such devices are less complex than devices that rely on other physical phenomena for their operation, such as interference, resonance or grating phenomena. They have potential application to a wide range of applications including optical telecommunications, optical sensing and biophotonics. The major outcome will be a range of novel devices that are very compact, have very low optical power loss and process light signals in ways that either cannot be readily achieved by other approaches or are simpler than other approaches.Read moreRead less
Development of an advanced semiconductor characterisation capability for infrared focal plane array applications. Australian access to world leading technology in state-of-the-art infrared detectors is key to future advanced systems for defence surveillance and sensing, mineral exploration, biomedical instrumentation, precision agriculture, environmental monitoring and homeland security. This project will ensure that Australia contributes to an integral component required in the development of t ....Development of an advanced semiconductor characterisation capability for infrared focal plane array applications. Australian access to world leading technology in state-of-the-art infrared detectors is key to future advanced systems for defence surveillance and sensing, mineral exploration, biomedical instrumentation, precision agriculture, environmental monitoring and homeland security. This project will ensure that Australia contributes to an integral component required in the development of these technologies allowing early access to future systems. It will also enable Austarlia to play a leading role in setting the research directions for infrared materials that will place Australian research at the forefront in this area.Read moreRead less
Development of inert gas ion beams for fabrication of nano-structures. This project will develop a high brightness, high density ion beam for reactive fabrication of structures with dimensions of the order of and less than 100 nano-metres. Present systems use liquid metal ion sources which can pollute the substrates being fabricated. Use of inert gas ions will overcome this problem and lead to a new type of ion source to replace the older systems. Added advantages include significantly increased ....Development of inert gas ion beams for fabrication of nano-structures. This project will develop a high brightness, high density ion beam for reactive fabrication of structures with dimensions of the order of and less than 100 nano-metres. Present systems use liquid metal ion sources which can pollute the substrates being fabricated. Use of inert gas ions will overcome this problem and lead to a new type of ion source to replace the older systems. Added advantages include significantly increased lifetime much higher reproducibility. Our commercial collaborator, FEI Company, estimate the world market as being $US100,000,000 and will actively promote this technology worldwide when it is fully developed.Read moreRead less
Verification and prototypes of Opto-ULSI Processors for MicroPhotonic Applications. The aim of the program is to establish efficient linkage between Australia and Korea by stimulating research towards the rapid integration of VLSI systems into photonic components, hence creating a new platform in intelligent MicroPhotonic systems, which are core elements for future-generation reconfigurable telecommunication networks. Our ultimate target is to (1) design a low-power 256-phase Opto-ULSI processor ....Verification and prototypes of Opto-ULSI Processors for MicroPhotonic Applications. The aim of the program is to establish efficient linkage between Australia and Korea by stimulating research towards the rapid integration of VLSI systems into photonic components, hence creating a new platform in intelligent MicroPhotonic systems, which are core elements for future-generation reconfigurable telecommunication networks. Our ultimate target is to (1) design a low-power 256-phase Opto-ULSI processor, (2) experimentally verify various reconfigurable MicroPhotonic architectures for optical telecommunication applications, (3) develop efficient software for the various MicroPhotonic systems, and (4) develop and verify working prototypes.Read moreRead less
Implant Isolation of III-V Compound Semiconductor Devices and Structures. Individual devices in an integrated circuit can be electrically isolated from each other by irradiating the materials between them with high energy ions. This creates defects in the semiconductor that trap charge carriers and thereby increase the resistance of the material. However, the effectiveness of this process depends on the material as well as irradiation and post-irradiation processing conditions. This project aim ....Implant Isolation of III-V Compound Semiconductor Devices and Structures. Individual devices in an integrated circuit can be electrically isolated from each other by irradiating the materials between them with high energy ions. This creates defects in the semiconductor that trap charge carriers and thereby increase the resistance of the material. However, the effectiveness of this process depends on the material as well as irradiation and post-irradiation processing conditions. This project aims to develop an implant isolation scheme for a new class of devices developed by Epitactix, an Australian start-up company founded on CSIRO research. This will be achieved by combining the ANU's experience and expertise in ion-irradiation and defect engineering with the device and processing expertise of Epitactix Pty Ltd.Read moreRead less
Reconfigurable MicroPhotonic Processor. This research aims to study a new reconfigurable MicroPhotonic processor capable of performing many optical functions simultaneously. In this project, research is particularly focused on reconfigurable optical add/drop multiplexing (ROADM) for future Dense Wavelength Division Multiplexed (DWDM) optical networks. The significance of the MicroPhotonic architecture is that it can add/drop a single or multiple wavelength channels, and can scale to tens of chan ....Reconfigurable MicroPhotonic Processor. This research aims to study a new reconfigurable MicroPhotonic processor capable of performing many optical functions simultaneously. In this project, research is particularly focused on reconfigurable optical add/drop multiplexing (ROADM) for future Dense Wavelength Division Multiplexed (DWDM) optical networks. The significance of the MicroPhotonic architecture is that it can add/drop a single or multiple wavelength channels, and can scale to tens of channels while maintaining low insertion loss and low crosstalk. The outcome will be a new reconfigurable MicroPhotonic ROADM architecture which overcomes existing scaling bottlenecks for processing hundreds of DWDM channels.Read moreRead less
Novel silicon photonic devices harnessing new leakage behaviour. The continuing advance of microprocessor performance requires vast quantities of data to be transferred between on-chip processor cores and to the outside world. The transfer of data via metal wires cannot meet this demand due to limited bandwidth and astonishing heat generation. Low-loss photonic transport integrated onto the silicon chip offers a solution. With this project we will explore harnessing a newly discovered phenomenon ....Novel silicon photonic devices harnessing new leakage behaviour. The continuing advance of microprocessor performance requires vast quantities of data to be transferred between on-chip processor cores and to the outside world. The transfer of data via metal wires cannot meet this demand due to limited bandwidth and astonishing heat generation. Low-loss photonic transport integrated onto the silicon chip offers a solution. With this project we will explore harnessing a newly discovered phenomenon in silicon photonics to achieve devices such as electrically pumped lasers and wavelength routers. The project will collaborate closely with researchers in the USA, but will focus on research of designs that can be created in Australia and licensed to major industry across the globe.
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Correlated electron states in ultra high purity quantum transistors. Ultra-fast transistors play a decisive role in modern telecommunications and are found in everything from mobile telephones to HD television. The rapid advances in transistor technology and its impact on society has recently been recognised by the award of the 2000 Nobel Prize in Physics for electronic device design. However the rapid advances in technology have reached the stage where unexpected new phenomena are being observe ....Correlated electron states in ultra high purity quantum transistors. Ultra-fast transistors play a decisive role in modern telecommunications and are found in everything from mobile telephones to HD television. The rapid advances in transistor technology and its impact on society has recently been recognised by the award of the 2000 Nobel Prize in Physics for electronic device design. However the rapid advances in technology have reached the stage where unexpected new phenomena are being observed in extremely high quality transistors that cannot be explained by existing theories. This proposal addresses this imbalance and aims to develop powerful theoretical tools to investigate unexplained quantum effects in ultra-high quality transistors.Read moreRead less