Biomimetic Design and Fabrication of Smart Dry Adhesives. Gecko footpads have unique structures with amazing features; imitating these fine bio-structures will lead to a multitude of innovations. This project aims to study fundamental principles governing adhesion phenomena for creating entirely new biomimetic nanomaterials with tunable adhesion, self-cleaning and controlled release capabilities. The gecko-mimicking materials and the associated dynamic effects will be characterized quantitativel ....Biomimetic Design and Fabrication of Smart Dry Adhesives. Gecko footpads have unique structures with amazing features; imitating these fine bio-structures will lead to a multitude of innovations. This project aims to study fundamental principles governing adhesion phenomena for creating entirely new biomimetic nanomaterials with tunable adhesion, self-cleaning and controlled release capabilities. The gecko-mimicking materials and the associated dynamic effects will be characterized quantitatively at multiscales and the nanoscale phenomena will be linked to macroscopic performance. The results of this research should provide a fundamental understanding of tunable adhesion mechanisms for the design and development of optimized materials with superb performance of practical significance.
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Quantum Nanostructure Positioning for Breakthrough Quantum Photonics. The integration of quantum nanostructures in optical devices has been proposed to improve the efficiencies of existing optical devices and create new classes of quantum photonics. Limiting progress is that many nanostructures are made through bottom-up processes with inherently randomly distributions, making integration into devices problematic. Lithographic nanostructure fabrication is rarely an option as it leads to diminish ....Quantum Nanostructure Positioning for Breakthrough Quantum Photonics. The integration of quantum nanostructures in optical devices has been proposed to improve the efficiencies of existing optical devices and create new classes of quantum photonics. Limiting progress is that many nanostructures are made through bottom-up processes with inherently randomly distributions, making integration into devices problematic. Lithographic nanostructure fabrication is rarely an option as it leads to diminishes performance. Here, we propose a new and unique nanostructure positioning technique incorporated directly into the growth process. It interfaces bottom-up technologies with device fabrication, facilitating incorporation of nanostructures in photonic devices, and may be transferrable to a variety of other systems.Read moreRead less
Nanofabrication of Metamaterials for Next Generation Optical Devices. The dream of invisibility cloaks dates back to ancient times but recent advances in nanotechnology have made this a reality through the use of metamaterials. Metamaterials are artificially-made materials that have optical properties not found in nature. This field is still in its infancy and significant challenges remain and need to be solved before practical applications can be realised. This project builds on Australia’s str ....Nanofabrication of Metamaterials for Next Generation Optical Devices. The dream of invisibility cloaks dates back to ancient times but recent advances in nanotechnology have made this a reality through the use of metamaterials. Metamaterials are artificially-made materials that have optical properties not found in nature. This field is still in its infancy and significant challenges remain and need to be solved before practical applications can be realised. This project builds on Australia’s strategic investment in nanofabrication capabilities to fabricate functional metamaterials and uncover the underlying physical phenomena. It will revolutionise the field of nanophotonics for a variety of novel applications ranging from defence, renewable energy, imaging, sensing to optical communications.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100071
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Light-bending strategies of next generation scalable plasmonic devices. This project will focus on a goal of engineering novel plasmonic metamaterials for manipulating light at the nanoscale. In particular, it will employ curved anodized alumina templates as well as 3D hybrid structures to explore light bending and strong resonances at the visible spectral range. Plasmonic metamaterials offer a unique ability to control subwavelength light propagation, for achieving unprecedented sensing sensiti ....Light-bending strategies of next generation scalable plasmonic devices. This project will focus on a goal of engineering novel plasmonic metamaterials for manipulating light at the nanoscale. In particular, it will employ curved anodized alumina templates as well as 3D hybrid structures to explore light bending and strong resonances at the visible spectral range. Plasmonic metamaterials offer a unique ability to control subwavelength light propagation, for achieving unprecedented sensing sensitivities and emerging nanophotonics phenomena. However, fabrication challenges and high losses hamper their application in the visible spectral range. Engineering these plasmonic structures in a scalable manner should strengthen Australia’s economy, lead to new industrial companies in the emerging field of plasmonics, attract international investments and create job opportunities.Read moreRead less
Quantum Nanophotonics with Atomically Thin Materials . This project aims to deliver new hardware for scalable integrated quantum photonics based on fluorescent defects in hexagonal boron nitride. The project will generate new knowledge in advanced manufacturing of two-dimensional systems, to pivot towards engineering of new optical qubits. Expected outcomes include a solid-state platform for on-chip quantum technologies and development of sovereign quantum capabilities. The results will constitu ....Quantum Nanophotonics with Atomically Thin Materials . This project aims to deliver new hardware for scalable integrated quantum photonics based on fluorescent defects in hexagonal boron nitride. The project will generate new knowledge in advanced manufacturing of two-dimensional systems, to pivot towards engineering of new optical qubits. Expected outcomes include a solid-state platform for on-chip quantum technologies and development of sovereign quantum capabilities. The results will constitute an important step towards implementation of secure communications and quantum information protocols. Benefits include advances in emerging manufacturing capabilities, training of young Australians, generation of intellectual property and securing major economic benefits to all Australians.Read moreRead less
Hexagonal boron nitride for deep ultraviolet device applications. This project plans to investigate the growth of an alternative material, hexagonal boron nitride, for use in high performance deep-ultraviolet (UV) light-emitting diodes (LEDs). Deep-UV LEDs are robust and highly portable devices that replace traditional mercury/deuterium-based UV sources, and have applications in water or air sterilisation, photo-dermal therapy, covert communication and bio-chemical agent identification. However, ....Hexagonal boron nitride for deep ultraviolet device applications. This project plans to investigate the growth of an alternative material, hexagonal boron nitride, for use in high performance deep-ultraviolet (UV) light-emitting diodes (LEDs). Deep-UV LEDs are robust and highly portable devices that replace traditional mercury/deuterium-based UV sources, and have applications in water or air sterilisation, photo-dermal therapy, covert communication and bio-chemical agent identification. However, despite major worldwide effort in the development of aluminium gallium nitride deep-UV LEDs, their efficiency is still extremely low. Understanding the fundamental growth, doping and alloying mechanisms of hexagonal boron nitride will allow us to engineer its properties and create high-efficiency devices.Read moreRead less