Special Research Initiatives - Grant ID: SR180100023
Funder
Australian Research Council
Funding Amount
$940,000.00
Summary
Thermal decomposition of PFAS. This project aims to investigate the thermal decomposition of per- and poly-fluroalkyl substances (PFAS). The project will focus on the catalytic destruction of PFAS reactions at elevated temperatures, which is expected to transform PFAS in a controlled and predictable way into benign products. By understanding the fate of these compounds during thermal decomposition, the project will allow the development of a new technology aimed at treating materials which have ....Thermal decomposition of PFAS. This project aims to investigate the thermal decomposition of per- and poly-fluroalkyl substances (PFAS). The project will focus on the catalytic destruction of PFAS reactions at elevated temperatures, which is expected to transform PFAS in a controlled and predictable way into benign products. By understanding the fate of these compounds during thermal decomposition, the project will allow the development of a new technology aimed at treating materials which have been contaminated with or have been used as absorbants for PFAS. The project will provide the technical underpinning of a new technology developed to treat fluorochemical-contaminated material and, in doing so, reduce the environmental impact of these contaminants.Read moreRead less
Accessing Liquid Noble Metals for Low Temperature Chemical Reactions. We will explore noble metals in liquid form at low temperatures. We will show that while noble metals melting points are above 1000°C, a gallium matrix will allow their existence in liquid form at low temperatures (<75°C). A variety of noble metal gallium alloy combinations will be investigated for their catalytic activities which are expected to show very high kinetics. We will study both bulk and low dimensional analogues to ....Accessing Liquid Noble Metals for Low Temperature Chemical Reactions. We will explore noble metals in liquid form at low temperatures. We will show that while noble metals melting points are above 1000°C, a gallium matrix will allow their existence in liquid form at low temperatures (<75°C). A variety of noble metal gallium alloy combinations will be investigated for their catalytic activities which are expected to show very high kinetics. We will study both bulk and low dimensional analogues to understand the atomic dispersion of noble metals on interface and in the core of the alloys, for discoveries regarding the liquid state catalytic properties of the mixes. Subsequently, model chemical reactions will reveal the enhancement of the kinetics and what the project can offer to industrial innovations. Read moreRead less
Liquid metal solvents for high entropy and atomically configured systems. Significant challenges remain in developing high entropy alloys, which are future disruptors in metallurgy, ranging from configurational entropy to atomic ordering. To address such challenges, we will explore liquid metal solvents for synthesising high entropy and atomically configured systems from the combination of reactive and high melting point elements stabilised in metallic solvents. Molecular imprinting, mechanical ....Liquid metal solvents for high entropy and atomically configured systems. Significant challenges remain in developing high entropy alloys, which are future disruptors in metallurgy, ranging from configurational entropy to atomic ordering. To address such challenges, we will explore liquid metal solvents for synthesising high entropy and atomically configured systems from the combination of reactive and high melting point elements stabilised in metallic solvents. Molecular imprinting, mechanical and electrochemical triggers will control interfacial atomic organisation and precipitation. The growth mechanisms, both at the interface and in the bulk, will be explored by high energy probing techniques and computational simulations. We will offer new metallurgical paradigms for future catalysis and sensing concepts.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
Epitaxial Stacking of Nanoporous Nanosheets for Next-generation Membranes. The project aims to develop high-precision selective membranes which are urgently needed in Australian key industries for solute-solute separation by constructing vertically-aligned and chemically-tailorable nanochannels using two-dimensional porous nanosheets as building blocks. The project expects to generate advanced knowledge in the areas of nanosheet synthesis and functionalisation, membrane design and fabrication, s ....Epitaxial Stacking of Nanoporous Nanosheets for Next-generation Membranes. The project aims to develop high-precision selective membranes which are urgently needed in Australian key industries for solute-solute separation by constructing vertically-aligned and chemically-tailorable nanochannels using two-dimensional porous nanosheets as building blocks. The project expects to generate advanced knowledge in the areas of nanosheet synthesis and functionalisation, membrane design and fabrication, selective transport of solutes and applications. The membranes developed in the project should make existing separation processes more effective and sustainable and advance emerging applications in pharmaceutical, dairy and mining industries, providing significant economic and environmental benefits to Australia.Read moreRead less
Bioelectronics: addressing the biointerface challenge. This project aims to develop bioelectronic materials with long operational stability in physiological conditions and enhanced electronic performance that will effectively interface with electroresponsive tissue. These new materials will be integrated into bioadhesives from which simple bioelectronics devices will be fabricated and assessed for their capability to modulate biosignals and to interact with tissue. Disruption in biosignals cause ....Bioelectronics: addressing the biointerface challenge. This project aims to develop bioelectronic materials with long operational stability in physiological conditions and enhanced electronic performance that will effectively interface with electroresponsive tissue. These new materials will be integrated into bioadhesives from which simple bioelectronics devices will be fabricated and assessed for their capability to modulate biosignals and to interact with tissue. Disruption in biosignals causes numerous medical conditions such as epilepsy and heart failure and the development of flexible and biocompatible medical electronics devices that interface with tissue is essential for regaining and modulating these signals.Read moreRead less
Simultaneous dissolved methane and nitrogen removal. Direct anaerobic treatment of wastewater converts majority of organic matters in wastewater to methane, an energy source. However, up to 50% of the methane produced stays dissolved in wastewater. Its subsequent stripping to atmosphere in aerobic treatment not only causes significant loss of energy but also emission of a potent greenhouse gas. This project aims to develop a technology that not only avoids methane stripping but also enables its ....Simultaneous dissolved methane and nitrogen removal. Direct anaerobic treatment of wastewater converts majority of organic matters in wastewater to methane, an energy source. However, up to 50% of the methane produced stays dissolved in wastewater. Its subsequent stripping to atmosphere in aerobic treatment not only causes significant loss of energy but also emission of a potent greenhouse gas. This project aims to develop a technology that not only avoids methane stripping but also enables its beneficial use to enhance nitrogen removal, which is otherwise typically unsatisfactory due to the lack of organic carbon to support denitrification. The project will provide strong support to the Australian water industry in their endeavour to achieve energy- and carbon-neutral wastewater services.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH200100010
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Research Hub for Transformation of Reclaimed Waste Resources to Engineered Materials and Solutions for a Circular Economy. This project aims to create new knowledge to reduce waste going to landfills and transform reclaimed waste into new materials for use in construction and other manufacturing sectors. It integrates multisector input and multidisciplinary academic research to address ten challenging waste streams. Expected outcomes are smart materials, socio-technical change, accelerated t ....ARC Research Hub for Transformation of Reclaimed Waste Resources to Engineered Materials and Solutions for a Circular Economy. This project aims to create new knowledge to reduce waste going to landfills and transform reclaimed waste into new materials for use in construction and other manufacturing sectors. It integrates multisector input and multidisciplinary academic research to address ten challenging waste streams. Expected outcomes are smart materials, socio-technical change, accelerated testing methods, predictive modeling, circular life cycle costing and a trusted evidence base. Outcomes will lead to commercial benefits as well as jobs and a significant contribution to addressing the pressing environmental impacts of waste production, management, and re-use.Read moreRead less
Advanced separators for lithium-sulphur batteries. This project aims to develop new membranes for use as separators in lithium-sulphur batteries. Currently diffusion of polysulphides within these batteries reduces battery power and lifetime. The new membranes are intended to block polysulphide diffusion over an extended lifetime, while transporting the other ions needed for the battery to function. The project is expected to generate new membrane materials and further knowledge about the design, ....Advanced separators for lithium-sulphur batteries. This project aims to develop new membranes for use as separators in lithium-sulphur batteries. Currently diffusion of polysulphides within these batteries reduces battery power and lifetime. The new membranes are intended to block polysulphide diffusion over an extended lifetime, while transporting the other ions needed for the battery to function. The project is expected to generate new membrane materials and further knowledge about the design, synthesis and larger-scale production of membranes for electrochemical applications. This project will provide significant benefits by producing potentially lighter, longer-lasting and cheaper batteries than existing lithium-ion technologies, with the potential to accelerate the adoption of electric cars.Read moreRead less
Airborne ultrafine particles in Australian cities. There is an acute deficiency of knowledge in Australia on urban airborne ultrafine particles, originating from transport and other anthropogenic sources, which pose significant health and environmental risks. The aim of this project is to address this deficiency by an extensive multi-city, cross-disciplinary study using state of the art instrumentation and data analytic techniques. The outcome will be an in depth, quantitative insight into the c ....Airborne ultrafine particles in Australian cities. There is an acute deficiency of knowledge in Australia on urban airborne ultrafine particles, originating from transport and other anthropogenic sources, which pose significant health and environmental risks. The aim of this project is to address this deficiency by an extensive multi-city, cross-disciplinary study using state of the art instrumentation and data analytic techniques. The outcome will be an in depth, quantitative insight into the characteristics of the particles, their sources and spatial and temporal variation across different urban areas and time scales. Further, the impacts of changing fuels, vehicle technologies, and climate on future trends of the particles will be elucidated.Read moreRead less