Exploration of lead free ferroelectric crystals for transducer applications. This project aims to investigate lead free crystals, which are expected to possess high piezoelectric properties for medical imaging and underwater acoustics, as an alternative to toxic lead-based ferroelectrics which have been dominantly used in ultrasound transducers. The project will have significant impact on development of new lead-free ferroelectric crystals with desirable properties. This will benefit Australian ....Exploration of lead free ferroelectric crystals for transducer applications. This project aims to investigate lead free crystals, which are expected to possess high piezoelectric properties for medical imaging and underwater acoustics, as an alternative to toxic lead-based ferroelectrics which have been dominantly used in ultrasound transducers. The project will have significant impact on development of new lead-free ferroelectric crystals with desirable properties. This will benefit Australian industry by providing knowledge and technology of crystal growth, enabling advanced ultrasound transducers for medical imaging and underwater acoustic 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
Catalytic production of health food additives from crustacean wastes. Cost-effective production of new synthetic amino acids as value-added food additives from crustacean wastes is vital for waste recycling and a sustainable economy. This project will develop a unique catalytic system for the selective conversion of waste-derived compounds into tailor-made products. Advanced in situ spectroscopic techniques will be employed to establish the structure-reactivity relationship of working catalysts ....Catalytic production of health food additives from crustacean wastes. Cost-effective production of new synthetic amino acids as value-added food additives from crustacean wastes is vital for waste recycling and a sustainable economy. This project will develop a unique catalytic system for the selective conversion of waste-derived compounds into tailor-made products. Advanced in situ spectroscopic techniques will be employed to establish the structure-reactivity relationship of working catalysts and thereby manipulate the key factors governing the activity/selectivity. Such cutting-edge knowledge gained is crucial for optimising process effciency and resource utilisation, which is essential for the success of the biorefining industry and a more environmentally-friendly chemical and food economy in Australia.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
Discovery Early Career Researcher Award - Grant ID: DE220100429
Funder
Australian Research Council
Funding Amount
$406,177.00
Summary
Bioinspired Photocatalysts for Solar-Driven Hydrogen Peroxide Production. This project aims to develop advanced photocatalysts that can efficiently produce hydrogen peroxide from just water, air, and sunlight. By mimicking the structure and function of the natural photosynthetic apparatus, the key innovations are expected in the design of reaction-oriented conjugated polymer-based photocatalysts at the atomic and molecular nanostructure levels. It expects to generate new knowledge in artificial ....Bioinspired Photocatalysts for Solar-Driven Hydrogen Peroxide Production. This project aims to develop advanced photocatalysts that can efficiently produce hydrogen peroxide from just water, air, and sunlight. By mimicking the structure and function of the natural photosynthetic apparatus, the key innovations are expected in the design of reaction-oriented conjugated polymer-based photocatalysts at the atomic and molecular nanostructure levels. It expects to generate new knowledge in artificial photosynthesis and rational design of functional materials, and sustainable technology for hydrogen peroxide production. This cross-disciplinary research will benefit Australia by the development of biomimetic catalysts for advancing solar energy conversion and enabling sustainable manufacturing of commodity chemicals. Read moreRead less
Interface structures mediating load transfer between soft and hard tissues. This project aims to develop a novel technology platform to mediate load transfer between synthetic and biological materials with dissimilar mechanical properties, creating an effective interface mechanism. It will generate new knowledge in materials engineering by combining interdisciplinary expertise and state-of-the-art technologies in computational modelling, biomaterials, and additive manufacturing. Expected outcome ....Interface structures mediating load transfer between soft and hard tissues. This project aims to develop a novel technology platform to mediate load transfer between synthetic and biological materials with dissimilar mechanical properties, creating an effective interface mechanism. It will generate new knowledge in materials engineering by combining interdisciplinary expertise and state-of-the-art technologies in computational modelling, biomaterials, and additive manufacturing. Expected outcomes are high-tech ceramic structures optimized to interface effectively between synthetic soft tissues and natural hard tissues. This could ultimately benefit Australian industry engaged in developing next-generation synthetic orthopaedic solutions, providing a significant competitive advantage in an expanding global market.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL190100216
Funder
Australian Research Council
Funding Amount
$3,279,753.00
Summary
Plasma surface engineering for break-through technologies in biomedicine. This program aims to develop new plasma surface modification processes for complex porous structures using a strongly multidisciplinary approach combining plasma physics, materials engineering and expertise from biosciences. It will establish fundamental new understanding of plasma interactions within complex materials by combining innovations in simulation and experiment. Expected outcomes will be new research capacity i ....Plasma surface engineering for break-through technologies in biomedicine. This program aims to develop new plasma surface modification processes for complex porous structures using a strongly multidisciplinary approach combining plasma physics, materials engineering and expertise from biosciences. It will establish fundamental new understanding of plasma interactions within complex materials by combining innovations in simulation and experiment. Expected outcomes will be new research capacity in the increasingly important field of bioengineering, and environmentally friendly plasma processes that enable the creation of robust biologically functional surfaces, providing significant benefits for diagnostic and therapeutic biomedical applications.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH210100023
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Research Hub for Functional and Sustainable Fibres. This Research Hub aims to expand Australia’s position in fibres, textiles and composites by developing next generation functional fibre materials and creating synergy between functionality and sustainability, two key attributes that have hitherto been mutually exclusive. The Hub will transform regional and national economies from traditional manufacturing to a vibrant future fibre oriented advanced manufacturing sector with functionality an ....ARC Research Hub for Functional and Sustainable Fibres. This Research Hub aims to expand Australia’s position in fibres, textiles and composites by developing next generation functional fibre materials and creating synergy between functionality and sustainability, two key attributes that have hitherto been mutually exclusive. The Hub will transform regional and national economies from traditional manufacturing to a vibrant future fibre oriented advanced manufacturing sector with functionality and sustainability as central tenets. Expected outcomes include industry adoption of novel fibre-based materials, processing and recycling technologies; creating jobs, significant environmental benefits, and positioning Australia at the front of a global shift towards functional and sustainable materials.Read moreRead less
Powering Next Generation Wearable Electronics: Moisture Electric Generator . This project aims to develop next generation energy harvesting device which can directly generate electricity from the moisture in the air for self-powered, wearable electronics. The goal will be achieved by developing a new class of carbon based nanomaterials and large scale printing technology, through optimizing the materials defects, printing process and electrode configuration. The expected outcomes will be new el ....Powering Next Generation Wearable Electronics: Moisture Electric Generator . This project aims to develop next generation energy harvesting device which can directly generate electricity from the moisture in the air for self-powered, wearable electronics. The goal will be achieved by developing a new class of carbon based nanomaterials and large scale printing technology, through optimizing the materials defects, printing process and electrode configuration. The expected outcomes will be new electronic materials for a wide range of end uses in wearable electronics, significant advances in self-powered, environmentally friendly devices, and commercialisation of the technology to Australian industries.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