Rechargeable lithium carbon dioxide battery - catalyst design to prototype . This project aims to develop a new concept of rechargeable lithium carbon dioxide batteries and scaled-up prototypes. Such a battery will be first of its kind to show high power comparable to gasoline and superior rechargeability over existing gas-involved batteries, ensuring realistic use for industrial purposes. Expected outcomes include 2-dimensional catalysts made from earth-abundant elements lowering large-scale pr ....Rechargeable lithium carbon dioxide battery - catalyst design to prototype . This project aims to develop a new concept of rechargeable lithium carbon dioxide batteries and scaled-up prototypes. Such a battery will be first of its kind to show high power comparable to gasoline and superior rechargeability over existing gas-involved batteries, ensuring realistic use for industrial purposes. Expected outcomes include 2-dimensional catalysts made from earth-abundant elements lowering large-scale production cost, a novel but reliable working principle based on reversible carbon dioxide/oxalate conversion, and prototypes featuring high specific capacity, large energy density and excellent durability. Via industrial pilot trials, commercial benefits will be fast tracked for energy security and carbon dioxide utilisation.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170101069
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Two-dimensional inorganic nanostructures for hydrogen evolution reaction. This project aims to synthesise highly active electrochemical catalysts of two-dimensional (2D) inorganic nanostructure for hydrogen evolution reaction (HER). The electrocatalysis of water to produce hydrogen gas could generate clean energy, but the platinum catalyst’s cost and low activity make it impractical. This project will develop 2D inorganic nanosheets with tuneable pores and electronic band structures, hybridised ....Two-dimensional inorganic nanostructures for hydrogen evolution reaction. This project aims to synthesise highly active electrochemical catalysts of two-dimensional (2D) inorganic nanostructure for hydrogen evolution reaction (HER). The electrocatalysis of water to produce hydrogen gas could generate clean energy, but the platinum catalyst’s cost and low activity make it impractical. This project will develop 2D inorganic nanosheets with tuneable pores and electronic band structures, hybridised with organic and/or inorganic semiconductor nanomaterials for HER, and use density functional theory calculation to investigate these hybridised nanosheets’ mechanisms for HER. These highly efficient and low-cost catalysts are expected to generate clean energy and create opportunities for Australian industries.Read moreRead less
Perovskite-Based Ferroelectrics for Solar Fuel Production. This project aims to develop perovskite-based ferroelectrics for photocatalytic carbon dioxide reduction to produce solar fuels. It is expected to reveal the relationship of ferroelectric polarisation and photocatalytic behaviour, thereby promoting solar energy utilisation and greenhouse gas reduction. Expected outcomes include delivery of a novel family of chemically and structurally controlled ferroelectrics and catalytic reaction prot ....Perovskite-Based Ferroelectrics for Solar Fuel Production. This project aims to develop perovskite-based ferroelectrics for photocatalytic carbon dioxide reduction to produce solar fuels. It is expected to reveal the relationship of ferroelectric polarisation and photocatalytic behaviour, thereby promoting solar energy utilisation and greenhouse gas reduction. Expected outcomes include delivery of a novel family of chemically and structurally controlled ferroelectrics and catalytic reaction prototypes for efficient carbon dioxide photoreduction, and in-depth understanding of structure-performance correlation to guide future polar catalysts design. This project should provide significant benefits in minimising fossil fuel consumption, increasing energy security, and expanding clean energy industry.Read moreRead less
Monolithic Solar Thermal Photocatalytic Membrane for Hydrogen Production. This ambitious project aims to develop a new concept of monolithic membranes composed of photocatalysts embedded in highly efficient solar thermal graphene. Such a membrane will be first of its kind and is able to utilise full solar spectrum for scalable seawater desalination and direct splitting to produce hydrogen without the need to concentrate sunlight. Expected outcomes include chemically and structurally tailored mem ....Monolithic Solar Thermal Photocatalytic Membrane for Hydrogen Production. This ambitious project aims to develop a new concept of monolithic membranes composed of photocatalysts embedded in highly efficient solar thermal graphene. Such a membrane will be first of its kind and is able to utilise full solar spectrum for scalable seawater desalination and direct splitting to produce hydrogen without the need to concentrate sunlight. Expected outcomes include chemically and structurally tailored membranes and 2D floating prototypes for real life hydrogen production, and in-depth understanding of working mechanism to facilitate up-scaled renewable hydrogen generation. Significant benefits in minimising fossil fuel consumption, increasing energy security, and expanding competitive clean energy industry are promised.Read moreRead less
High temperature corrosion induced by multiple secondary oxidants . Heat resisting chromia-forming alloys passivate successfully in clean, dry air at temperatures up to about 950°C. However, this performance is degraded by secondary oxidants (carbon, sulphur, chlorine, water vapour), leading to corrosion failure in important industries. The project aims to investigate the effect of these secondary oxidants on corrosion behaviour of chromia-forming alloys, to identify interactions between multipl ....High temperature corrosion induced by multiple secondary oxidants . Heat resisting chromia-forming alloys passivate successfully in clean, dry air at temperatures up to about 950°C. However, this performance is degraded by secondary oxidants (carbon, sulphur, chlorine, water vapour), leading to corrosion failure in important industries. The project aims to investigate the effect of these secondary oxidants on corrosion behaviour of chromia-forming alloys, to identify interactions between multiple oxidants within the scale, to establish the mechanisms of oxide scale penetration by foreign species, and to evaluate scales on different alloy types. The results will provide a basis for improved design/selection of heat resisting chromia-forming alloys, key to power generation industries.Read moreRead less
Wearable thermoelectric textiles for portable microelectronics. Wearable thermoelectrics enable the power generation from the temperature difference between human body and ambient temperature by using thermoelectric effect. This project aims to design eco-friendly wearable thermoelectric textiles to realize high-efficiency solid-state power generation and meet individual needs with human comfort and health. The target is to achieve a power density in the as-designed thermoelectric textiles by th ....Wearable thermoelectric textiles for portable microelectronics. Wearable thermoelectrics enable the power generation from the temperature difference between human body and ambient temperature by using thermoelectric effect. This project aims to design eco-friendly wearable thermoelectric textiles to realize high-efficiency solid-state power generation and meet individual needs with human comfort and health. The target is to achieve a power density in the as-designed thermoelectric textiles by the optimization of materials and device design. The outcome will open up a new platform for the green and sustainable charge for portable microelectronics, which will lead to an innovative technology for energy management, which will place Australia at the forefront of wearable electronics and textile industry.Read moreRead less
Hybrid photocatalytic nanomaterials for water purification. This project aims to synthesise and characterise a range of porous photocatalytic materials (materials that absorb light to catalyse a reaction), and to establish high-throughput processes to simultaneously test the effectiveness of multiple photocatalytic materials. This interdisciplinary project expects to develop two new techniques that will lead to faster materials optimisation of materials that breakdown organic pollutants in water ....Hybrid photocatalytic nanomaterials for water purification. This project aims to synthesise and characterise a range of porous photocatalytic materials (materials that absorb light to catalyse a reaction), and to establish high-throughput processes to simultaneously test the effectiveness of multiple photocatalytic materials. This interdisciplinary project expects to develop two new techniques that will lead to faster materials optimisation of materials that breakdown organic pollutants in water under light irradiation. The intended outcomes include the production of industrially relevant photocatalysts and building capability in Australia to decrease photocatalytic testing time and cost. This should provide significant benefits to industry and the environment, and have an impact on human health.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
Core loss mechanisms in soft magnetic nanostructures. This project aims to clarify the mechanism of power losses in magnetic cores used in the petrol-electric hybrid cars by investigating the relationship between the core losses and magnetic correlation lengths in iron alloys. This project expects to generate new knowledge on the effect of magneto-mechanical interaction on the anomalous core loss in iron based alloys. The intended outcomes include an experimental confirmation of the random aniso ....Core loss mechanisms in soft magnetic nanostructures. This project aims to clarify the mechanism of power losses in magnetic cores used in the petrol-electric hybrid cars by investigating the relationship between the core losses and magnetic correlation lengths in iron alloys. This project expects to generate new knowledge on the effect of magneto-mechanical interaction on the anomalous core loss in iron based alloys. The intended outcomes include an experimental confirmation of the random anisotropy model, a major theoretical model in nanostructured materials and identification of ideal magnetic domain configurations for lower power losses. These intended outcomes should bring great benefits to the development of low-carbon vehicle technologies for sustainable motorisation in Australia.Read moreRead less
Doped alumina with tailored material properties for battery applications. This project aims to develop tailored alumina materials for lithium ion battery separators through a novel in-situ approach that will: (1) produce uniform doped alumina for improved safety, (2) target specific surface and bulk material properties to increase the overall performance, and (3) reduce manufacturing costs by integrating the process with new technology developed for the production of high purity alumina. Signifi ....Doped alumina with tailored material properties for battery applications. This project aims to develop tailored alumina materials for lithium ion battery separators through a novel in-situ approach that will: (1) produce uniform doped alumina for improved safety, (2) target specific surface and bulk material properties to increase the overall performance, and (3) reduce manufacturing costs by integrating the process with new technology developed for the production of high purity alumina. Significant advances are proposed for overcoming current manufacturing limitations of doped alumina. Building research capacity and knowledge in battery material manufacturing will benefit a range of industries across Australia, whilst providing new opportunities for growth in local communities.Read moreRead less