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Nanoarchitectonics of carbon nanomaterials. This project aims to develop a generic nanoarchitectonic method to create functional macroscopic carbon architectures using carbon nanomaterials. The project will manipulate the interactions among individual nanostructures by combining bottom-up synthesis with macroscopic wet spinning/knitting or three-dimensional printing assembly processes, leading to functionalities that contrast strongly with conventional nanotechnology. It will demonstrate the tec ....Nanoarchitectonics of carbon nanomaterials. This project aims to develop a generic nanoarchitectonic method to create functional macroscopic carbon architectures using carbon nanomaterials. The project will manipulate the interactions among individual nanostructures by combining bottom-up synthesis with macroscopic wet spinning/knitting or three-dimensional printing assembly processes, leading to functionalities that contrast strongly with conventional nanotechnology. It will demonstrate the technical feasibility of fabric supercapacitors, wearable strain/moisture sensors and carbon membranes. This project is expected to move the fundamental research of nanomaterials to advanced manufacturing techniques.Read moreRead less
Advanced three-dimensional fibrous structures for vascular graft applications. This project will combine advanced three-dimensional fabric structures, surface functionalisation and haemodynamic modelling to tackle critical issues in the design and manufacture of vascular graft materials. It will lead to the next generation of vascular grafts with much enhanced structural and biomedical performance.
Piezoelectric nanofibre membranes with built-in p-n junction: new self-rectifying piezoelectric power generators. This project will aim to develop new knowledge about how to efficiently convert small mechanical energy into directly usable electric power using piezoelectric nanofibre membranes and will fill this knowledge gap by systematically understanding the influence of doping agents on the charge transport during energy conversion.
Industrial Transformation Research Hubs - Grant ID: IH140100018
Funder
Australian Research Council
Funding Amount
$4,711,583.00
Summary
ARC Research Hub for a World-class Future Fibre Industry. ARC Research Hub for a World-class Future Fibre Industry. This research hub aims to transform the Australian fibre industry into a dynamic sector focused on high-performance and high-value fibres and fibre-based products. Capitalising on the research team's combined strength in fibre science and technology, and working with highly innovative small and medium enterprises and international research leaders, the hub seeks to develop advance ....ARC Research Hub for a World-class Future Fibre Industry. ARC Research Hub for a World-class Future Fibre Industry. This research hub aims to transform the Australian fibre industry into a dynamic sector focused on high-performance and high-value fibres and fibre-based products. Capitalising on the research team's combined strength in fibre science and technology, and working with highly innovative small and medium enterprises and international research leaders, the hub seeks to develop advanced carbon fibres, nanofibres and high-performance novel fibres, as well as value-added applications of fibre materials. These materials are expected to help to reduce energy costs, minimise the environmental footprint of manufacturing processes and improve public health and safety. The hub will also train the next generation of industry-savvy fibre research leaders.Read moreRead less
Microstructure effect on energy harvesting ability of electrospun fibres. This project aims to provide new knowledge about how to manipulate the energy harvesting ability of electrospun fibrous mats by changing the fibre structure, components and mat configuration. Expected outcomes of the project are new fibrous materials capable of efficiently converting small mechanical forces and sounds into electricity. These high performance energy harvesting fibres will be useful for developing new power ....Microstructure effect on energy harvesting ability of electrospun fibres. This project aims to provide new knowledge about how to manipulate the energy harvesting ability of electrospun fibrous mats by changing the fibre structure, components and mat configuration. Expected outcomes of the project are new fibrous materials capable of efficiently converting small mechanical forces and sounds into electricity. These high performance energy harvesting fibres will be useful for developing new power supplies, self-powered electronics, self-sustainable sensor networks and electronic textiles.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100517
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Development of hybrid carbon nanotube yarn and processing methods to create 3D smart materials and devices. The project aims to create 'intelligent' textiles by developing novel electroactive yarns and demonstrating scaled up processing through adapted knitting, weaving and braiding techniques. By tailoring their structure these unique carbon nanotubes can be made to act as sensors or artificial muscles.
Segmental fibres having periodically-repeating multicomponent segments from T-junction microfluidic electrospinning. Segmental fibres, which have periodically-repeating multi-component segments along their length, represent a new fibre type offering enormous potential in creating new fibre functions. The present work aims to develop a technical platform to prepare segmental fibres and new knowledge on how the fibre segments contribute to the property, functionality and inter-fibrous interaction ....Segmental fibres having periodically-repeating multicomponent segments from T-junction microfluidic electrospinning. Segmental fibres, which have periodically-repeating multi-component segments along their length, represent a new fibre type offering enormous potential in creating new fibre functions. The present work aims to develop a technical platform to prepare segmental fibres and new knowledge on how the fibre segments contribute to the property, functionality and inter-fibrous interaction of fibres. This will be achieved using a special microfluidic electrospinning technique. The segmental fibres developed will be useful for development of various new functional fibres for diverse applications. Read moreRead less
Superwettability effects on oil-mist coalescing fibrous filters. This project aims to provide new knowledge about how to use surface engineering techniques to produce highly efficient, energy-saving fibrous filters for separating oil mists from air streams. The focus is to address the challenge of the low efficiency of current generation coalescing filters for removal of oil mists smaller than one micrometre. The project will result in new methods to precisely control fibre surface wettability a ....Superwettability effects on oil-mist coalescing fibrous filters. This project aims to provide new knowledge about how to use surface engineering techniques to produce highly efficient, energy-saving fibrous filters for separating oil mists from air streams. The focus is to address the challenge of the low efficiency of current generation coalescing filters for removal of oil mists smaller than one micrometre. The project will result in new methods to precisely control fibre surface wettability and oil drainage within fibrous filters. The new knowledge and coalescing filters developed will benefit scientific and industrial fields including metal processing, automotive, engineering and manufacturing, electronics, food, hospital, mining, pharmaceuticals and energy generation.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100070
Funder
Australian Research Council
Funding Amount
$241,500.00
Summary
Automated Fibre Braiding Facility for Multifunctional Structural Materials. Automated fibre braiding facility for multifunctional structural materials:
This project seeks to establish an Australian automated braiding facility to create innovative fibrous materials with multiple functionalities. This facility aims to provide Australian researchers with the capabilities of high-speed, precision and versatility to radially braid single or multiple filament types including carbon, metal, optical, n ....Automated Fibre Braiding Facility for Multifunctional Structural Materials. Automated fibre braiding facility for multifunctional structural materials:
This project seeks to establish an Australian automated braiding facility to create innovative fibrous materials with multiple functionalities. This facility aims to provide Australian researchers with the capabilities of high-speed, precision and versatility to radially braid single or multiple filament types including carbon, metal, optical, natural, bio-inspired and bio-compatible fibres and filaments to create new materials with unique functional properties. The facility would be able to braid over multiple length scales spanning nanofibres to millimetre-sized filaments to create novel materials and shapes not possible using other processing techniques. Expected applications include new materials for building, self-healing, human protection and biomedicine. Read moreRead less
Directional fluid-transfer in thin porous materials with gradient wettability through thickness. This project will further strengthen Australia's world leading position in advanced fibrous materials research. It will provide a new platform technology to develop self-driven unidirectional fluid-transfer fabrics and porous membranes for diverse applications in daily life, healthcare, defence and a number of industrial processes.