Photonic routing with liquid crystals. Liquid crystals became a household item but their unequaled nonlocal optical properties are much less known and studied, although the breathtaking prospects of their future applications in photonics inspire many experts around the world. We will bring to Australia the state of the art research approach, theoretical and experimental, aiming to uncover and realize the potential of long range interaction between laser light and nonlocal liquid crystals for fut ....Photonic routing with liquid crystals. Liquid crystals became a household item but their unequaled nonlocal optical properties are much less known and studied, although the breathtaking prospects of their future applications in photonics inspire many experts around the world. We will bring to Australia the state of the art research approach, theoretical and experimental, aiming to uncover and realize the potential of long range interaction between laser light and nonlocal liquid crystals for futuristic all-optical devices. This project will promote and enhance the rapid development of photonics in Australia, as well as deliver foremost practical expertise and outstanding training of young researchers.Read moreRead less
Centre for Ultrahigh-bandwidth Devices for Optical Systems. The Centre, through a ground-breaking research program, will in the next five years invent and develop a set of revolutionary optical devices and will integrate these devices onto a photonic chip, for the use in the next generation of ultra-high bandwidth optical telecommunications systems. These systems will dramatically improve online services to the Australian community in key areas such as health, education and business connectivity ....Centre for Ultrahigh-bandwidth Devices for Optical Systems. The Centre, through a ground-breaking research program, will in the next five years invent and develop a set of revolutionary optical devices and will integrate these devices onto a photonic chip, for the use in the next generation of ultra-high bandwidth optical telecommunications systems. These systems will dramatically improve online services to the Australian community in key areas such as health, education and business connectivity. Australia's high tech industry will benefit from the commercialisation opportunities arising from the Centre's research, and also from the creation of a pool of highly skilled ICT professionals.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775668
Funder
Australian Research Council
Funding Amount
$210,000.00
Summary
Direct write - microphotonics fabrication facility. Direct write-microfabrication, where an ultrafast laser is focussed to a small, intense spot and translated under computer control with respect to a target sample, has emerged as a significant enabling technology creating new opportunities in microphotonics. The proposed facility will enable researchers to modify the internal properties of glass blocks and write 'optical wires' (or waveguides). By combining waveguides with other laser written f ....Direct write - microphotonics fabrication facility. Direct write-microfabrication, where an ultrafast laser is focussed to a small, intense spot and translated under computer control with respect to a target sample, has emerged as a significant enabling technology creating new opportunities in microphotonics. The proposed facility will enable researchers to modify the internal properties of glass blocks and write 'optical wires' (or waveguides). By combining waveguides with other laser written functional components researchers will develop devices capable of processing optical information. Outcomes will include demonstrations of compact lasers and slow light generation.Read moreRead less
Integrated magneto-optic waveguide materials and devices. We aim to develop chalcogenide glass films for fabricating integrated waveguide magneto-optic (MO) devices as a radical alternative to the use of crystalline MO materials that have proven difficult to manufacture in integrated form. Using our ultra-fast pulsed laser deposition (UFPLD) technique we will produce a wide range of chalcogenide glass compositions through combinatorial materials synthesis and assess them for magneto-optic activ ....Integrated magneto-optic waveguide materials and devices. We aim to develop chalcogenide glass films for fabricating integrated waveguide magneto-optic (MO) devices as a radical alternative to the use of crystalline MO materials that have proven difficult to manufacture in integrated form. Using our ultra-fast pulsed laser deposition (UFPLD) technique we will produce a wide range of chalcogenide glass compositions through combinatorial materials synthesis and assess them for magneto-optic activity. UFPLD will also be used to deposit high optical quality films for device prototyping. We will design and fabricate prototype MO components which are essential, but currently unavailable, for use as optical isolators in integrated optics.Read moreRead less
Advanced Siloxane Waveguide Devices for Telecommunications. This project will develop new methods for fabricating compact, high performance photonic integrated circuits (PICs) for use in future telecommunications networks in films of proprietary Inorganic Polymer Glasses (IPGs) commercialised by RPO Pty Ltd. New fabrication methods are required to overcome limitations of the current approach to patterning IPGs used by RPO Pty Ltd. Research will concentrate on hard contact lithography in conjunct ....Advanced Siloxane Waveguide Devices for Telecommunications. This project will develop new methods for fabricating compact, high performance photonic integrated circuits (PICs) for use in future telecommunications networks in films of proprietary Inorganic Polymer Glasses (IPGs) commercialised by RPO Pty Ltd. New fabrication methods are required to overcome limitations of the current approach to patterning IPGs used by RPO Pty Ltd. Research will concentrate on hard contact lithography in conjunction with dry (plasma) etching as well as ion beam milling; laser machining or UV writing for grating production. IPGs present special challenges for these technologies. The project outcomes will include new approaches to processing and the demonstration of the fabrication of innovative PICs in IPGs.Read moreRead less
Technologies for space-based optical interferometry. Gravitational waves are ripples in the curvature of space-time produced by the motion of massive celestial objects. Gravitational waves provide a different kind of information about the universe and their measurement will lead to an entirely new type of astronomy. The quest to detect gravitational waves is entering a new era with the Laser Interferometer Space Antenna (LISA) now under development. LISA is a two billion dollar joint NASA/ESA de ....Technologies for space-based optical interferometry. Gravitational waves are ripples in the curvature of space-time produced by the motion of massive celestial objects. Gravitational waves provide a different kind of information about the universe and their measurement will lead to an entirely new type of astronomy. The quest to detect gravitational waves is entering a new era with the Laser Interferometer Space Antenna (LISA) now under development. LISA is a two billion dollar joint NASA/ESA deep space mission to build a gravitational wave observatory in space. This research will develop Australian technologies critical to the success of LISA and other future deep space missions.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453541
Funder
Australian Research Council
Funding Amount
$298,052.00
Summary
Raman Photonic Device Facility. We are seeking funding for an Raman Photonic Device Facility. This represents a new opportunity for Australia to become a world leader in the rapidly advancing area of Raman interactions in photonic devices covering both real-world application and fundamental physical research. The equipment request comprises ultrafast and high-power laser systems, forming a unique integrated facility within Australia. This facility will link Australia's premier research organizat ....Raman Photonic Device Facility. We are seeking funding for an Raman Photonic Device Facility. This represents a new opportunity for Australia to become a world leader in the rapidly advancing area of Raman interactions in photonic devices covering both real-world application and fundamental physical research. The equipment request comprises ultrafast and high-power laser systems, forming a unique integrated facility within Australia. This facility will link Australia's premier research organization in the area of photonics, including the University of Sydney, Macquarie University and The Australian National University.Read moreRead less
Ion implantation engineered photonic devices for use in highly integrated silicon optoelectronic circuits. This project establishes a collaboration with Canada's leading integrated silicon photonics research group thus tapping into years of valuable experience transferable to Australian-based researchers. The involvement of students as well as early career researchers ensures a new generation of Australian experts in this field. The importance of silicon photonics means that Australia must estab ....Ion implantation engineered photonic devices for use in highly integrated silicon optoelectronic circuits. This project establishes a collaboration with Canada's leading integrated silicon photonics research group thus tapping into years of valuable experience transferable to Australian-based researchers. The involvement of students as well as early career researchers ensures a new generation of Australian experts in this field. The importance of silicon photonics means that Australia must establish a strong research program in the area to maintain its current position as being at the forefront of leading-edge research. This is only possible through collaborations such as that proposed here.Read moreRead less
Defect-induced luminescence from ion-implanted silicon: Towards silicon photonics applications. This project focusses on advanced materials science, photonics and innovative silicon optical devices that have potential for contributing to information and communications technologies, areas where Australia has considerable expertise and investment. Specifically, national benefit will be derived from breakthroughs in fundamental science and intellectual property.
Rare Earth doped chalcogenide glass films for on-chip optical amplifiers. The project will contribute to Australia's strong record of achievement in photonics technology. It has the potential to migrate photonic chip technology for all-optical processing from laboratory demonstrations to a commercially viable technology. If this is achieved commercialisation through a start-up company will become possible. All-optical processing is an advanced technology that will help increase the speed and the ....Rare Earth doped chalcogenide glass films for on-chip optical amplifiers. The project will contribute to Australia's strong record of achievement in photonics technology. It has the potential to migrate photonic chip technology for all-optical processing from laboratory demonstrations to a commercially viable technology. If this is achieved commercialisation through a start-up company will become possible. All-optical processing is an advanced technology that will help increase the speed and the bandwidth of optical communications systems and the internet.Read moreRead less