Development of Metal-Titania Core-Shell Nanostructures for Photocatalysis. The aim of this project is to develop innovative techniques for the synthesis of advanced nanomaterials for pollutant removal and antibacterial applications. Improving the photocatalysis efficiency of titanium oxide (TiO2) is critical in energy and environmental applications. This project aims to develop innovative strategies to prepare metal–TiO2 core-shell nanostructures, in which metals (eg gold, silver) can be used as ....Development of Metal-Titania Core-Shell Nanostructures for Photocatalysis. The aim of this project is to develop innovative techniques for the synthesis of advanced nanomaterials for pollutant removal and antibacterial applications. Improving the photocatalysis efficiency of titanium oxide (TiO2) is critical in energy and environmental applications. This project aims to develop innovative strategies to prepare metal–TiO2 core-shell nanostructures, in which metals (eg gold, silver) can be used as light absorbers for visible incident light and generate intense electromagnetic fields, thus improving efficiency.Read moreRead less
Nanoscale control of energy and matter for future energy-efficient technologies. Unprecedented control of energy and matter in nanoscale fabrication will be achieved using non-equilibrium self-organised plasma-solid systems. The outcomes will lead to energy-efficient, environment- and human-health-friendly production of nanomaterials for future energy, health, information, food, water, environmental and security technologies.
Programming soft plasmene nanosheets with living RAFT functional polymers. This project aims to use recently discovered plasmene to demonstrate programmable materials properties using living RAFT polymeric ligands. Plasmene is free-standing, one-particle-thick, superlattice sheets of plasmonic nanoparticles. It represents a conceptually new class of two-dimensional metamaterials with broad applications in energy, environment, sensors and optoelectronic devices. This project expects to generate n ....Programming soft plasmene nanosheets with living RAFT functional polymers. This project aims to use recently discovered plasmene to demonstrate programmable materials properties using living RAFT polymeric ligands. Plasmene is free-standing, one-particle-thick, superlattice sheets of plasmonic nanoparticles. It represents a conceptually new class of two-dimensional metamaterials with broad applications in energy, environment, sensors and optoelectronic devices. This project expects to generate new knowledge and patentable technologies, and advance Australian worldwide standing in the field of nanotechnology and polymer science.Read moreRead less
Organically-Capped Copper Nanowires for Soft Electronic Skin Sensors. Soft skin-like electronics can enable applications that are impossible to achieve with today's rigid circuit board technologies. However, it is difficult to realise such future soft electronics with traditional materials and conventional manufacturing methodologies. This project aims to synthesise novel organically-capped copper nanowires as electronic inks (e-inks) for developing cost-effective, soft, stretchable conductor (e ....Organically-Capped Copper Nanowires for Soft Electronic Skin Sensors. Soft skin-like electronics can enable applications that are impossible to achieve with today's rigid circuit board technologies. However, it is difficult to realise such future soft electronics with traditional materials and conventional manufacturing methodologies. This project aims to synthesise novel organically-capped copper nanowires as electronic inks (e-inks) for developing cost-effective, soft, stretchable conductor (e-skin) sensors, which are wearable for monitoring blood pulses, body motions and hand gestures in real-time and in situ. This is expected to advance our knowledge in nanotechnology and generate patentable technologies in soft e-skin sensors, and to bring significant scientific and economic gains to Australia.Read moreRead less
Soft Plasmene Nanosheets for Stretchable Plasmonic Skins. Conventional plasmonic sensors and devices are rigid, planar, and not stretchable. This project aims to apply plasmene materials developed at Monash's Nanobionics lab to design highly stretchable plasmonic devices (artificial plasmonic skins). Systematic experimental and theoretical studies will be undertaken to understand how the plasmonic skins respond to strains and how they can be used for fabricating novel stretchable devices. Such s ....Soft Plasmene Nanosheets for Stretchable Plasmonic Skins. Conventional plasmonic sensors and devices are rigid, planar, and not stretchable. This project aims to apply plasmene materials developed at Monash's Nanobionics lab to design highly stretchable plasmonic devices (artificial plasmonic skins). Systematic experimental and theoretical studies will be undertaken to understand how the plasmonic skins respond to strains and how they can be used for fabricating novel stretchable devices. Such studies will generate important new knowledge of fabrication, characterisation, and modelling of stretchable plasmene, hence, contributing to further Australian standing in the field of nanotechnology and plasmonics. It may also incubate patentable technologies, bringing potential economic gains.Read moreRead less
Ultrastretchable, Highly Transparent, Wearable Gold Nanowire Generators. Next-generation wearable electronics should be thin, soft and even transparent, enabling applications impossible to achieve with traditional rigid electronics. Such future electronics will require disruptive soft skin-conformal energy devices to power. This project aims to develop a bi-modal gold nanowire percolation strategy to design ultrathin conductors that are electrically conductive, optically transparent and mechanic ....Ultrastretchable, Highly Transparent, Wearable Gold Nanowire Generators. Next-generation wearable electronics should be thin, soft and even transparent, enabling applications impossible to achieve with traditional rigid electronics. Such future electronics will require disruptive soft skin-conformal energy devices to power. This project aims to develop a bi-modal gold nanowire percolation strategy to design ultrathin conductors that are electrically conductive, optically transparent and mechanically stretchable. It expects to generate new knowledge in nanomaterials design and new technologies to fabricate skin-like invisible wearable generators. This should provide significant benefits in advancing Australian standing in the fields of nanotechnology and energy science, and bringing potential economic gains.Read moreRead less
Developing Multi-Scale Technologies for Two-Dimensional Metal Nanoparticle Superlattice Sheets. Nanoparticle superlattices refer to highly ordered nanoparticle arrays, which are a new class of crystalline materials with collective properties different from those of bulk phase crystals, isolated nanocrystals and even disordered nanocrystal assemblies. However nanoparticle superlattice is still in the embryonic stage of development due to the lack of multiscale technologies. This project aims to d ....Developing Multi-Scale Technologies for Two-Dimensional Metal Nanoparticle Superlattice Sheets. Nanoparticle superlattices refer to highly ordered nanoparticle arrays, which are a new class of crystalline materials with collective properties different from those of bulk phase crystals, isolated nanocrystals and even disordered nanocrystal assemblies. However nanoparticle superlattice is still in the embryonic stage of development due to the lack of multiscale technologies. This project aims to develop such important technologies to produce two-dimensional nanoparticle superlattice sheets for novel energy-harvesting devices. This will generate new knowledge and important patentable technologies for future energy industries, contributing to further advance Australian knowledge base and build a greener world.Read moreRead less
Highly durable electronic skins for multifunctional tactile sensing. This project aims to develop next-generation, multifunctional, wearable tactile sensors that can perceive and discriminate between different types of physical and chemical stimuli. These wearable e-skin sensors will mimic the sensing capabilities of real skin, and will measure a broader range of aspects of a person’s physical and biological condition than current wearable sensors. It will generate a new platform technology capa ....Highly durable electronic skins for multifunctional tactile sensing. This project aims to develop next-generation, multifunctional, wearable tactile sensors that can perceive and discriminate between different types of physical and chemical stimuli. These wearable e-skin sensors will mimic the sensing capabilities of real skin, and will measure a broader range of aspects of a person’s physical and biological condition than current wearable sensors. It will generate a new platform technology capable of commercialisation, bringing economic gains to Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100592
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Fabrication strategies for nanophotonic devices. The project will develop novel strategies to engineer nanophotonic entities to control and guide light at the nanoscale. These nanostructures will open up new avenues for integrated multifunctional devices spanning sensing, light emission and quantum communications, positioning Australia at the frontier of nanoscience and quantum technologies.
Electronics out of thin air: MAGIC - Metal–Air Gated Integrated Circuits. We constantly seek faster, lighter, and energy-efficient devices. This project will create a new class of electronic devices, re-inventing vacuum tubes that enabled electronics almost a century ago, and scaling them down to the nanoscale realm. The devices are termed vacuum channel transistors, and transistors are the critical functional element of all electronics. At the extremely small size scales for nanoelectronics, th ....Electronics out of thin air: MAGIC - Metal–Air Gated Integrated Circuits. We constantly seek faster, lighter, and energy-efficient devices. This project will create a new class of electronic devices, re-inventing vacuum tubes that enabled electronics almost a century ago, and scaling them down to the nanoscale realm. The devices are termed vacuum channel transistors, and transistors are the critical functional element of all electronics. At the extremely small size scales for nanoelectronics, the charge carriers travel very short distances. This avoids collisions enabling extremely high-speed transport. Such a virtual vacuum environment can potentially enable electronics thousands of times faster than the current silicon-based technology, providing a solution to the challenges faced by the semiconductor industry.Read moreRead less