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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
Cold catalysis for water splitting. This project aims to develop photocatalysts via AC magnetic field through nanoscale heating for efficient H2 generation. This project is to introduce cold catalysis concept, which heats catalysts only but not solution, thus called cold catalysis, in the area of production of renewable energy. Expected outcome is the creation of clean and low cost catalysts to effectively harvest the chemical energy from the sun via splitting of water into H2 and O2 without cau ....Cold catalysis for water splitting. This project aims to develop photocatalysts via AC magnetic field through nanoscale heating for efficient H2 generation. This project is to introduce cold catalysis concept, which heats catalysts only but not solution, thus called cold catalysis, in the area of production of renewable energy. Expected outcome is the creation of clean and low cost catalysts to effectively harvest the chemical energy from the sun via splitting of water into H2 and O2 without causing any environmental damage. This unique technology will also help to address clean energy generation, which is in line with H2 economy plan by Australia government, and provide opportunities for new industries that will benefit Australian economy.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
Photonic crystals: The key to breaking the silicon-solar cell efficiency barrier. This project aims to investigate solar light harvesting using light trapping by photonic crystal on an amorphous-Silicon thin-film combining passivation technologies with light trapping. Using this new light trapping method, based on a specially designed periodic surface structure, the project expects to set a new standard in solar energy conversion efficiency. The expected outcomes of this project represent a ste ....Photonic crystals: The key to breaking the silicon-solar cell efficiency barrier. This project aims to investigate solar light harvesting using light trapping by photonic crystal on an amorphous-Silicon thin-film combining passivation technologies with light trapping. Using this new light trapping method, based on a specially designed periodic surface structure, the project expects to set a new standard in solar energy conversion efficiency. The expected outcomes of this project represent a step change in Silicon solar cell efficiency, applicable to different materials and especially useful for thin flexible cells. The project has the potential to benefit the renewable energy sector, increasing the efficiency of sustainable energy production, with positive economic and environmental impacts.Read moreRead less
Understand ion-specific effects under nanoconfinement by multiscale models. Different types of ions with the same charge can behave distinctively in many ionic applications. This so-called ion-specific effect is essential to ion separation, ion sensing, electrochemical energy storage, chemical and biomedical processes and many other industrial applications. Confining ions in nanopores and modulating them via surface electric potential can give rise to new ion-specific effects, enabling novel app ....Understand ion-specific effects under nanoconfinement by multiscale models. Different types of ions with the same charge can behave distinctively in many ionic applications. This so-called ion-specific effect is essential to ion separation, ion sensing, electrochemical energy storage, chemical and biomedical processes and many other industrial applications. Confining ions in nanopores and modulating them via surface electric potential can give rise to new ion-specific effects, enabling novel applications. Capitalising on our recent experimental discoveries, this project aims to integrate new multiscale models to understand ion-specific effects in electroconductive nanoporous materials. The new models will be used to quantitatively predict ion-specific effects in supercapacitor design.Read moreRead less
Bespoke nanomaterials for understanding nano-bio interactions under flow. This project aims to develop innovative scalable synthesis techniques to produce polymeric nanomaterials with controlled properties and characterise interactions between nanomaterials and cells under flow conditions. This project expects to generate new knowledge in priority research areas of nanotechnology, polymer chemistry and immunology. The outcome of this project is an original scalable and environmentally friendly t ....Bespoke nanomaterials for understanding nano-bio interactions under flow. This project aims to develop innovative scalable synthesis techniques to produce polymeric nanomaterials with controlled properties and characterise interactions between nanomaterials and cells under flow conditions. This project expects to generate new knowledge in priority research areas of nanotechnology, polymer chemistry and immunology. The outcome of this project is an original scalable and environmentally friendly technology, new knowledge of cell-nanomaterial interactions and new design principles for nanoparticles with potential future applications in drug delivery, immunology and nanomedicine. This project should provide significant benefits to polymer, nanomaterial and pharmaceutical research and industry in Australia.Read moreRead less
Thermally conductive materials from boron nitride nanosheets. This project aims to produce novel two-dimensional nanomaterials, in the form of functionalised boron nitride nanosheets and investigate their chemical, thermal and mechanical properties. The project expects to design and develop unique boron nitride nanosheets with targeted thermally conductive and electrically insulating properties, to address the critical technological problem of heat management in electronic devices. The resulting ....Thermally conductive materials from boron nitride nanosheets. This project aims to produce novel two-dimensional nanomaterials, in the form of functionalised boron nitride nanosheets and investigate their chemical, thermal and mechanical properties. The project expects to design and develop unique boron nitride nanosheets with targeted thermally conductive and electrically insulating properties, to address the critical technological problem of heat management in electronic devices. The resulting new nanoscience and ground breaking design and processing techniques will have the capacity to address the current technical obstacles which are preventing further development of fast and smaller electronic devices.Read moreRead less
Developing novel two-dimensional hybrid nanostructures for renewable energy. This project aims to develop novel two-dimensional (2D) hybrid nanostructures with new physical and chemical properties. This innovation intends to address the critical challenges of control functionalisation of 2D hybrid nanostructures: essential to understanding the potential of nanomaterials in key applications of energy generation. Expected outcomes include scalable technology to produce functional 2D nanomaterials ....Developing novel two-dimensional hybrid nanostructures for renewable energy. This project aims to develop novel two-dimensional (2D) hybrid nanostructures with new physical and chemical properties. This innovation intends to address the critical challenges of control functionalisation of 2D hybrid nanostructures: essential to understanding the potential of nanomaterials in key applications of energy generation. Expected outcomes include scalable technology to produce functional 2D nanomaterials and hybrid nanostructures to accelerate research to advanced materials and frontier material manufacturing technologies. This project will provide significant social and economic benefits to Australia in the growth of sectors in advanced materials, energy generation, and advanced manufacturing.Read moreRead less
A systems materials engineering strategy for hybrid ion capacitors. This project aims to develop a data science-driven approach to allow the use of materials systems engineering strategy to quantify the cell-level design of electrochemical energy storage devices such as hybrid ion capacitors. The intended outcomes of this project include new dynamic equivalent circuit models and a new quantitative approach to make the electrodes pairing predictable and realise their optimal design against the ne ....A systems materials engineering strategy for hybrid ion capacitors. This project aims to develop a data science-driven approach to allow the use of materials systems engineering strategy to quantify the cell-level design of electrochemical energy storage devices such as hybrid ion capacitors. The intended outcomes of this project include new dynamic equivalent circuit models and a new quantitative approach to make the electrodes pairing predictable and realise their optimal design against the needs of the specific applications. It will also demonstrate a combined strategy of data science and discipline-specific experiments and theories to advance the emerging field of materials systems engineering. Read moreRead less
Design of 2D Soft Plasmonic Photocatalysts for Artificial Leaves. The project aims to fabricate 2D soft plasmonic photocatalysts with leaf-like structures and functions for solar-to chemical energy conversions. The proposed 2D photocatalysts expect to change the traditional way of designing artificial photocatalysts. Expected outcomes of this project include fabrication of 2D soft plasmonic photocatalyst with large-area, ultrathin thickness, and high flexibility, understanding their plasmon-enha ....Design of 2D Soft Plasmonic Photocatalysts for Artificial Leaves. The project aims to fabricate 2D soft plasmonic photocatalysts with leaf-like structures and functions for solar-to chemical energy conversions. The proposed 2D photocatalysts expect to change the traditional way of designing artificial photocatalysts. Expected outcomes of this project include fabrication of 2D soft plasmonic photocatalyst with large-area, ultrathin thickness, and high flexibility, understanding their plasmon-enhanced photocatalysis mechanisms, and construction of artificial leaves to perform the solar-to-chemical conversions, which can provide significant benefits, such as creating new-generation of soft energy devices and advancing Australian expertise in photochemistry, self-assembly, and functional nanomaterials.Read moreRead less