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
Discovery Early Career Researcher Award - Grant ID: DE230100383
Funder
Australian Research Council
Funding Amount
$450,554.00
Summary
Photothermal management with graphene metamaterials. Environmental and industrial thermal management represents major global energy consumption and CO2 emission. This project aims to investigate a game-changing passive thermal management solution to tackle both heating and cooling problems without using any electricity. This is made possible by designing a nanostructured graphene metamaterial to either totally reject or totally absorb electromagnetic waves in certain spectral ranges. Expected ou ....Photothermal management with graphene metamaterials. Environmental and industrial thermal management represents major global energy consumption and CO2 emission. This project aims to investigate a game-changing passive thermal management solution to tackle both heating and cooling problems without using any electricity. This is made possible by designing a nanostructured graphene metamaterial to either totally reject or totally absorb electromagnetic waves in certain spectral ranges. Expected outcomes include new design and fabrication strategies for novel photothermal films with high performance and cost-effectiveness. This is expected to lead to the development of novel energy efficient technologies for Australian industries, producing direct economic, social and environmental benefits.Read moreRead less
Early Career Industry Fellowships - Grant ID: IE230100048
Funder
Australian Research Council
Funding Amount
$466,097.00
Summary
Ammonium-selective membranes to shift water industry into circular economy. The project aims to develop ammonium-selective membranes which are urgently needed in Australian key industries for sustainable ammonia recovery. The project expects to construct the membranes to achieve desirable pore size and surface functionality for fast and selective ammonia transport. The developed membranes should make ammonia recovery from wastewater more effective and sustainable, leading to the healthy waterway ....Ammonium-selective membranes to shift water industry into circular economy. The project aims to develop ammonium-selective membranes which are urgently needed in Australian key industries for sustainable ammonia recovery. The project expects to construct the membranes to achieve desirable pore size and surface functionality for fast and selective ammonia transport. The developed membranes should make ammonia recovery from wastewater more effective and sustainable, leading to the healthy waterway and reduced energy for both ammonia production and removal. Recovered ammonia expects to produce valuable products, supporting agriculture industry and hydrogen economy. The developed membranes should enable water industry's shift into circular economy, providing significant economic and environmental benefits to Australia.Read moreRead less
Corrosion triggered self-passivation of magnesium alloys . This project aims to sustainably protect magnesium alloys from aqueous corrosion in engineering services through an unprecedented self-passivation mechanism (analogues to stainless steel). This project is expected to generate new knowledge in the area of passivation mechanisms for magnesium alloys in corrosive environments through high-throughput screening and in-situ corrosion characterisation at atomic scale. This should provide signif ....Corrosion triggered self-passivation of magnesium alloys . This project aims to sustainably protect magnesium alloys from aqueous corrosion in engineering services through an unprecedented self-passivation mechanism (analogues to stainless steel). This project is expected to generate new knowledge in the area of passivation mechanisms for magnesium alloys in corrosive environments through high-throughput screening and in-situ corrosion characterisation at atomic scale. This should provide significant benefits, such as enabling the debut of a scientific strategy to transform the magnesium alloy market with respect to end use (such as electric car industry), energy composition and emissions, which has significant industrial interest as it will provide new opportunities to minimise carbon footprint.Read moreRead less
Smart foliage: imparting intelligence to synthetic leaves. This project aims to develop an innovative “lab-on-a-leaf” platform technology based on smart membranes with switchable pores to enable hitherto unachievable control of gas and vapour transfer. The innovated membrane based technology can be used as a versatile platform for many important applications, such as desalination and carbon capture. This project expects to advance the knowledge in biomimetic design of synthetic leaves, and bring ....Smart foliage: imparting intelligence to synthetic leaves. This project aims to develop an innovative “lab-on-a-leaf” platform technology based on smart membranes with switchable pores to enable hitherto unachievable control of gas and vapour transfer. The innovated membrane based technology can be used as a versatile platform for many important applications, such as desalination and carbon capture. This project expects to advance the knowledge in biomimetic design of synthetic leaves, and bring new membrane technologies to applications, such as desalination, solar energy harvesting, and evaporative cooling. This project should provide significant benefits for Australian manufacturing industry by addressing energy and environmental concerns and boosting national economic growth.Read moreRead less
Advanced shield materials for compact fusion energy. We aim to predict how materials used for shielding sensitive components in nuclear fusion reactors will degrade over time. We will use this knowledge to design advanced alloys for radiation shield, which are critical for the development of more compact fusion reactors design, with lower construction cost, and shorter assembly time. These advanced shield materials may also be used in other applications in radiation fields (e.g. space, nuclear m ....Advanced shield materials for compact fusion energy. We aim to predict how materials used for shielding sensitive components in nuclear fusion reactors will degrade over time. We will use this knowledge to design advanced alloys for radiation shield, which are critical for the development of more compact fusion reactors design, with lower construction cost, and shorter assembly time. These advanced shield materials may also be used in other applications in radiation fields (e.g. space, nuclear medicine). The project also seeks to extend the Australian nuclear research capability by developing an innovative technique to study radiation damage using the OPAL reactor at ANSTO.Read moreRead less
Lightweight Photovoltaic Modules for Low-Load Capacity Building Roofs. This project aims to develop lightweight and reliable high efficiency photovoltaic modules that expand solar energy installations onto low-load capacity building roofs. New lightweight materials will be developed for packaging with multi-functionalities such as fast heat dissipation. This project will produce economical prototypes and enable and
facilitate cost reduction of crystalline silicon photovoltaic module installation ....Lightweight Photovoltaic Modules for Low-Load Capacity Building Roofs. This project aims to develop lightweight and reliable high efficiency photovoltaic modules that expand solar energy installations onto low-load capacity building roofs. New lightweight materials will be developed for packaging with multi-functionalities such as fast heat dissipation. This project will produce economical prototypes and enable and
facilitate cost reduction of crystalline silicon photovoltaic module installations on lightweight buildings, overcoming current constraints of heavy glass modules and making more solar energy exploited in both Australia’s urban and rural areas. This will get steps closer to zero emission buildings, by providing renewable energy alternative to conventional fossil fuel-based power generation.Read moreRead less
Unlocking the ion selectivity of lithium superionic conductor membranes. This project aims to address a longstanding challenge in designing advanced membranes to enable sustainable lithium refining by unlocking the ion selectivity of lithium superionic conductors. This project expects to generate new knowledge in the areas of membrane science and emerging nanoionics by using interdisciplinary approaches. Expected outcomes of this project include a novel class of lithium separation membranes and ....Unlocking the ion selectivity of lithium superionic conductor membranes. This project aims to address a longstanding challenge in designing advanced membranes to enable sustainable lithium refining by unlocking the ion selectivity of lithium superionic conductors. This project expects to generate new knowledge in the areas of membrane science and emerging nanoionics by using interdisciplinary approaches. Expected outcomes of this project include a novel class of lithium separation membranes and their fabrication techniques. This should provide significant benefits in improving lithium extraction and recycling efficiency, reducing their environmental impact and building the research capacity in advanced membrane manufacturing and critical mineral refining in Australia. 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: 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.
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