Boolean plasmonics: the design of nano-optical logic gates. The success of this project will see the development of an all-optical nano-scale logic gate. Such a device will drastically improve communications and information technology. Standard lithographic techniques will be used ensuring reproducibility and mass production, placing Australia at the forefront of the photonic market.
Bioinspired photoreceptor and smart neural mimicking technologies. The project aims to address fundamental questions regarding bioinspired artificial photoreceptors and neural-mimicking technologies that precisely mimic light capture abilities of photoreceptors, processing of retinal ganglion cells and functionalities in neurons. This is expected to generate new fundamental and applied knowledge in bioengineered optoelectronic systems. Expected outcomes of the project include new materials with ....Bioinspired photoreceptor and smart neural mimicking technologies. The project aims to address fundamental questions regarding bioinspired artificial photoreceptors and neural-mimicking technologies that precisely mimic light capture abilities of photoreceptors, processing of retinal ganglion cells and functionalities in neurons. This is expected to generate new fundamental and applied knowledge in bioengineered optoelectronic systems. Expected outcomes of the project include new materials with tailored properties at an atomic level for dynamic control of current under different light stimulus wavelengths. This should provide significant benefits such as new advanced materials driven smart architectures that overcome limitations of solid-state systems for next generation of smart technologies. Read moreRead less
Scalable atom-thin materials for monolithic electronics & optoelectronics. This project aims to understand large-area growth mechanisms and create practical, controllable doping methodologies for developing manufacturing-compatible tunable materials to overcome technological challenges presented by silicon. The project expects to generate new understanding of physico-chemical mechanisms that govern the optical and electrical properties of an emerging class of materials only few-atoms thick that ....Scalable atom-thin materials for monolithic electronics & optoelectronics. This project aims to understand large-area growth mechanisms and create practical, controllable doping methodologies for developing manufacturing-compatible tunable materials to overcome technological challenges presented by silicon. The project expects to generate new understanding of physico-chemical mechanisms that govern the optical and electrical properties of an emerging class of materials only few-atoms thick that offer unprecedented opportunities. This is expected to establish a suite of atomically-thin materials that will be deployed in miniaturised, high-density electronics and optoelectronics of which proof-of-concept functional devices are proposed to be demonstrated. These will be leveraged to explore industry partnerships.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100417
Funder
Australian Research Council
Funding Amount
$452,347.00
Summary
Light-emitting devices for next-generation optoelectronic applications. High-efficiency, multifunction light sources are essential in the new era of intelligent connectivity and hyper-automation for emerging applications in advanced display technologies (e.g., holographic/augmented reality displays), communication devices (e.g., 6th-generation (6G) telecommunication networks), and optical sensing (e.g., for self-driving vehicles & robotics). Realising such devices requires a paradigm shift in op ....Light-emitting devices for next-generation optoelectronic applications. High-efficiency, multifunction light sources are essential in the new era of intelligent connectivity and hyper-automation for emerging applications in advanced display technologies (e.g., holographic/augmented reality displays), communication devices (e.g., 6th-generation (6G) telecommunication networks), and optical sensing (e.g., for self-driving vehicles & robotics). Realising such devices requires a paradigm shift in optical technology beyond conventional optics. This project aims to develop new light-emitting device concepts that can deliver the technical requirements of these applications by tailoring advanced nanophotonic technologies and recent breakthroughs in advanced functional materials. Read moreRead less
Selective area nano-epitaxy. A new major program will be initiated to investigate the epitaxial growth of certain semiconductor nanowires on patterned substrates, without the use of a catalyst. It will result in the ability to produce nanowires of high quality and uniformity. This will lead the way for new and advanced concept nanowire-based devices for future applications.
Development and investigation of functional solid-state nano-pore membranes. This project aims to develop robust membranes with molecular size pores using atomically thin layers and silicon-based materials. Using state-of-the-art characterisation techniques and computer simulations it seeks to derive a fundamental understanding of the membrane formation processes and pore properties. Expected outcomes include industrially compatible fabrication processes that should enable rapid integration of t ....Development and investigation of functional solid-state nano-pore membranes. This project aims to develop robust membranes with molecular size pores using atomically thin layers and silicon-based materials. Using state-of-the-art characterisation techniques and computer simulations it seeks to derive a fundamental understanding of the membrane formation processes and pore properties. Expected outcomes include industrially compatible fabrication processes that should enable rapid integration of the membranes into advanced device applications as well as enhancing national capabilities for materials characterisation. Significant benefits should result from novel applications of the technologies in the areas of medical- and bio-sensing, filtration, and lab-on-the-chip devices.Read moreRead less
Antimonide-based nanowires for infra-red and energy applications. This project will investigate and to understand the fundamental growth mechanisms of antimonide-based semiconductor nanowires. It will result in the ability to produce nanowires of high quality and uniformity for applications in infra-red technologies such as photodetectors and solar cells.
Epitaxial growth of III-V microring lasers for integrated silicon photonics. This project aims to investigate the growth and demonstration of compound semiconductor microring lasers on silicon substrates, using selective area growth to engineer the shape of the lasing cavity at the nano/micro-scale. Silicon photonics is currently a dominant technology in optical and data communication systems, and the continued development demands higher speeds, lower power consumption and lower costs. However, ....Epitaxial growth of III-V microring lasers for integrated silicon photonics. This project aims to investigate the growth and demonstration of compound semiconductor microring lasers on silicon substrates, using selective area growth to engineer the shape of the lasing cavity at the nano/micro-scale. Silicon photonics is currently a dominant technology in optical and data communication systems, and the continued development demands higher speeds, lower power consumption and lower costs. However, on-chip integrated, high efficiency lasers are still elusive due to mismatch in material platforms between the lasers and silicon substrates. This project will produce reliable, efficient and easily manufacturable laser sources integrated on silicon photonic chips. It is also expected to pave the way for more development of this technology by the industry to further drive the cost of silicon photonics technology down whilst increasing data transmission speed.Read moreRead less
Electrically-driven semiconductor nanowire lasers. This project aims to investigate the concepts and strategies required to produce electrically injected semiconductor nanowire lasers. The project will achieve this by understanding light interaction in nanowires, designing appropriate structures to inject current and engineer optical profile and developing nano-fabrication technologies to make them. Electrically operated nanowire lasers would enable practical applications such as on-chip integra ....Electrically-driven semiconductor nanowire lasers. This project aims to investigate the concepts and strategies required to produce electrically injected semiconductor nanowire lasers. The project will achieve this by understanding light interaction in nanowires, designing appropriate structures to inject current and engineer optical profile and developing nano-fabrication technologies to make them. Electrically operated nanowire lasers would enable practical applications such as on-chip integrated optical systems and ultra-sensitive miniature sensors. The project is expected to pave the way for further development of this technology.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100004
Funder
Australian Research Council
Funding Amount
$470,000.00
Summary
Thin film processing cluster: precise synthesis and nano-patterning of functional coatings. This facility will allow Australian researchers to create advanced functional materials with unprecedented control over material configurations and near atomic scale precision in dimensions. This will enable significant advances in high speed photonics and electronics, health and environment monitoring, and micro-energy sources.