Multi-energy driven photothermal evaporators for all-weather desalination. This project aims to develop advanced Interfacial solar evaporation (ISE) technology to stably deliver clean water. This project expects to facilitate desalination practices by generating new ISE systems that use multiple energy sources from the environment and can operate under different weather conditions. Expected outcomes of this project include new knowledge in the area of renewable energy, improved ISE technique and ....Multi-energy driven photothermal evaporators for all-weather desalination. This project aims to develop advanced Interfacial solar evaporation (ISE) technology to stably deliver clean water. This project expects to facilitate desalination practices by generating new ISE systems that use multiple energy sources from the environment and can operate under different weather conditions. Expected outcomes of this project include new knowledge in the area of renewable energy, improved ISE technique and enhanced capacity for desalination and industrial wastewater treatment. This should provide significant benefits to remote communities who suffer from severe freshwater shortages and enhance research capabilities to position Australia as a global leader in developing green and affordable desalination technologies.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100357
Funder
Australian Research Council
Funding Amount
$409,118.00
Summary
Catalyst design for converting carbon dioxide into valuable chemicals. This project aims to use solar energy to convert carbon dioxide, the primary greenhouse gas that drives global climate change, into valuable chemicals via catalytic reduction. This project expects to facilitate the selective production of valuable ethylene from carbon dioxide reduction by developing novel cocatalyst materials derived from metal-oxo cluster molecules. Expected outcomes include fundamental understanding of the ....Catalyst design for converting carbon dioxide into valuable chemicals. This project aims to use solar energy to convert carbon dioxide, the primary greenhouse gas that drives global climate change, into valuable chemicals via catalytic reduction. This project expects to facilitate the selective production of valuable ethylene from carbon dioxide reduction by developing novel cocatalyst materials derived from metal-oxo cluster molecules. Expected outcomes include fundamental understanding of the structure-property relationship in new catalytic systems, and technological breakthroughs in reducing carbon dioxide emissions. The success of this project will bring significant environmental and economic benefits, and position Australia at the frontier of global transition to a low-carbon economy.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100480
Funder
Australian Research Council
Funding Amount
$445,237.00
Summary
Electrolyte design for high-performance, sustainable sodium batteries. This project aims to develop sustainable high-performance sodium batteries by investigating new non-flammable and safe electrolyte chemistries. The project will generate knowledge in materials chemistry for battery electrolytes that will underpin improvements in battery technology and help to move society towards a zero-carbon economy. The outcomes will provide materials suitable for prototyping reliable, safe and sustainable ....Electrolyte design for high-performance, sustainable sodium batteries. This project aims to develop sustainable high-performance sodium batteries by investigating new non-flammable and safe electrolyte chemistries. The project will generate knowledge in materials chemistry for battery electrolytes that will underpin improvements in battery technology and help to move society towards a zero-carbon economy. The outcomes will provide materials suitable for prototyping reliable, safe and sustainable batteries in Australia and enhance research collaborations with local and international industry partners. These advances will contribute to reliable, affordable, and sustainable energy storage systems, positioning Australia at the forefront of advanced battery research.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
Sustainable Electrocatalytic Synthesis of Urea. Urea is a critical chemical for agriculture, the chemical industry and pollution control, yet current production methods are unsustainable. This project aims to design high-efficiency catalysts for electrochemical urea synthesis from theoretical studies. This project expects to generate new knowledge of chemistry and catalysis from new reaction mechanisms and materials. Expected outcomes include optimum catalysts with high conversion efficiency and ....Sustainable Electrocatalytic Synthesis of Urea. Urea is a critical chemical for agriculture, the chemical industry and pollution control, yet current production methods are unsustainable. This project aims to design high-efficiency catalysts for electrochemical urea synthesis from theoretical studies. This project expects to generate new knowledge of chemistry and catalysis from new reaction mechanisms and materials. Expected outcomes include optimum catalysts with high conversion efficiency and reactant selectivity. The novel catalysts have the potential to deliver improved catalytic performance and controllable reaction reactants. This could deliver significant benefits to the crop production increase, cost reduction of chemical industry, and environmental pollution reduction.Read moreRead less
Two-dimensional nanomaterials for wearable zinc ion battery . The project aims to develop a new wearable battery system, based on advanced two-dimensional (2D) nanomaterials with robust energy storage performance and lifespan, for industrial application across the rapidly emerging industries of health monitoring, movement tracking, and smart clothing. The project addresses the critical challenges of control functionalization of advanced 2D nanomaterials for developing wearable energy storage. Th ....Two-dimensional nanomaterials for wearable zinc ion battery . The project aims to develop a new wearable battery system, based on advanced two-dimensional (2D) nanomaterials with robust energy storage performance and lifespan, for industrial application across the rapidly emerging industries of health monitoring, movement tracking, and smart clothing. The project addresses the critical challenges of control functionalization of advanced 2D nanomaterials for developing wearable energy storage. The research outcomes are expected to result in a scalable approach, a variety of advanced 2D nanomaterials, and wearable new battery system, which will bring significant economic and environmental, social, and cultural benefits to Australia and the world.Read moreRead less
Synthesis and Characterisation of Tracer-Functionalised Nanoparticles . This project aims to engineer nanomaterials by utilising gold nanochemistry and neural tracing capabilities of plant-based, nontoxic proteins. In a significant departure from current nanomaterials being developed, functionalising nanoparticles with the tracers enable them to undergo path-specific axonal retrograde transport, transneuronal transport, and anatomical tract flow to bypass the blood-brain barrier. Microfluidics w ....Synthesis and Characterisation of Tracer-Functionalised Nanoparticles . This project aims to engineer nanomaterials by utilising gold nanochemistry and neural tracing capabilities of plant-based, nontoxic proteins. In a significant departure from current nanomaterials being developed, functionalising nanoparticles with the tracers enable them to undergo path-specific axonal retrograde transport, transneuronal transport, and anatomical tract flow to bypass the blood-brain barrier. Microfluidics will be used to characterise the neuronal activities of the synthesised nanoconjugates of different sizes and compositions to understand their bio-interactions with axons, synapses, and neuromuscular junctions. The results will lead to a new class of functional nanomaterials as well as cell-based functional assays.Read moreRead less
Australian clays as raw materials of slow-release phosphate fertiliser. Phosphorus (P) fertiliser input in Australia is a significant problem for its inefficient plant uptake, leaching to natural water bodies and stocking of insoluble P in soil. The project aims to develop activated clays using Australian raw clay minerals to formulate effective slow-release phosphate (P) fertilisers (SRF) and delivery material for P-solubilising bacteria. Composite of these will supply P controllably even amid ....Australian clays as raw materials of slow-release phosphate fertiliser. Phosphorus (P) fertiliser input in Australia is a significant problem for its inefficient plant uptake, leaching to natural water bodies and stocking of insoluble P in soil. The project aims to develop activated clays using Australian raw clay minerals to formulate effective slow-release phosphate (P) fertilisers (SRF) and delivery material for P-solubilising bacteria. Composite of these will supply P controllably even amid environmental fluctuations but when a plant needs as it grows. Development of multifunctional, nontoxic and plant growth-driven P fertiliser would benefit improve soil fertility in a sustainable way where efficiency of P input is maximised with a minimised environmental burden.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100743
Funder
Australian Research Council
Funding Amount
$423,067.00
Summary
High-mobility transparent p-type materials synthesised from metal surfaces. This project aims to investigate the novel high mobility atomically thin materials synthesised from solid and liquid metal surfaces and to analyse the interfacial properties of their crystal. This project is expected to generate fundamental knowledge and applied research capability in interdisciplinary fields of advanced materials, nanomaterials, and electrical and chemical engineering using innovative synthesis approach ....High-mobility transparent p-type materials synthesised from metal surfaces. This project aims to investigate the novel high mobility atomically thin materials synthesised from solid and liquid metal surfaces and to analyse the interfacial properties of their crystal. This project is expected to generate fundamental knowledge and applied research capability in interdisciplinary fields of advanced materials, nanomaterials, and electrical and chemical engineering using innovative synthesis approaches. This project promises to support the development of new sustainable, low-waste and green technology for transparent, reliable, energy-efficient, high-performance nanoelectronics that can help to build high throughput and low dissipating power electronics components for energy generation, distribution and utilisation.
Read moreRead less
Designer Nanoparticles Enable mRNA Protein Factories. Intracellular delivery of mRNA facilitates target protein production, which could build protein factories that are essential in biomanufacturing industries. However, the instability of mRNA greatly lowers the protein production performance, limiting the commercial translation potential. This project aims to develop a new generation of nanoparticle delivery system to enhance mRNA stability against intracellular unstable cue, enzymatic digestio ....Designer Nanoparticles Enable mRNA Protein Factories. Intracellular delivery of mRNA facilitates target protein production, which could build protein factories that are essential in biomanufacturing industries. However, the instability of mRNA greatly lowers the protein production performance, limiting the commercial translation potential. This project aims to develop a new generation of nanoparticle delivery system to enhance mRNA stability against intracellular unstable cue, enzymatic digestion and thermal stress. This will be achieved by tailoring the nanochemistry at multi-scales. Expected outcomes include new knowledge in custom-design of functional nanomaterials for mRNA delivery, and new technology that will bring commercial benefits to the partner organisation and the biopharma sector.Read moreRead less