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
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
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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Discovery Early Career Researcher Award - Grant ID: DE170100021
Funder
Australian Research Council
Funding Amount
$370,000.00
Summary
Orchestrating cellular processes by engineering silicon nanowire architectures. This project aims to improve gene transport by creating low-cost, easily implemented, programmable and controllable silicon nanowire-mediated transfection technology, and to demonstrate high-throughput, parallel trafficking of bioactive payloads. Success would enable the design and fabrication of nano–bio interfaces with closely controlled geometry and architecture, to orchestrate specific cellular processes such as ....Orchestrating cellular processes by engineering silicon nanowire architectures. This project aims to improve gene transport by creating low-cost, easily implemented, programmable and controllable silicon nanowire-mediated transfection technology, and to demonstrate high-throughput, parallel trafficking of bioactive payloads. Success would enable the design and fabrication of nano–bio interfaces with closely controlled geometry and architecture, to orchestrate specific cellular processes such as cellular reprogramming, adhesion, morphology, and differentiation with unprecedented efficiency and predictability. The advance could lead to breakthroughs in fundamental cellular studies, and better understanding of cell behaviour, function and fate.Read moreRead less
Ultrathin Gold Nanocrystal Conductors for Wearable Epidermal Biofuel Cells. This project aims to fabricate ultrathin, soft yet stretchable gold nanocrystal conductors to push the thickness limit of next-generation soft bioelectrodes for fabrication of wearable epidermal biofuel cells. This will generate new knowledge and patentable technologies related to design/fabrication of soft nanocrystal conductors, bioanode and biocathode, which require to be thin, soft, conductive and biocompatible. Expe ....Ultrathin Gold Nanocrystal Conductors for Wearable Epidermal Biofuel Cells. This project aims to fabricate ultrathin, soft yet stretchable gold nanocrystal conductors to push the thickness limit of next-generation soft bioelectrodes for fabrication of wearable epidermal biofuel cells. This will generate new knowledge and patentable technologies related to design/fabrication of soft nanocrystal conductors, bioanode and biocathode, which require to be thin, soft, conductive and biocompatible. Expected outcomes of this project include enhanced national capacity in disruptive wearable bioelectronics, strengthening international collaborations, unskilled workforce training, as well as advancement of Australian knowledge base in the fields of nanotechnology, materials science, energy, biosensors and bioelectronics.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100704
Funder
Australian Research Council
Funding Amount
$355,000.00
Summary
Development of Two-Dimensional MnO2 Nanosheets for a theranostic platform. This project aims to develop a novel diagnostic and therapeutic nanoplatform for cancer treatment that will improve cancer diagnosis and monitoring of treatment and reduce the side-effects of chemotherapy. The platform, based on biocompatible, ultrasmall and targeted two-dimensional manganese-oxide nanosheets, aims to combine simultaneous targeting, stimuli-responsive magnetic resonance imaging and drug release and delive ....Development of Two-Dimensional MnO2 Nanosheets for a theranostic platform. This project aims to develop a novel diagnostic and therapeutic nanoplatform for cancer treatment that will improve cancer diagnosis and monitoring of treatment and reduce the side-effects of chemotherapy. The platform, based on biocompatible, ultrasmall and targeted two-dimensional manganese-oxide nanosheets, aims to combine simultaneous targeting, stimuli-responsive magnetic resonance imaging and drug release and delivery. This should enable precise imaging of tumour tissues and enhanced drug delivery triggered by the physiological tumour microenvironment. The translation of this technology into clinical practice is likely to have significant benefits for the efficient treatment of cancer.Read moreRead less