Integrated solar to chemical production and membrane concentration system. The efficient conversion of low-cost raw materials to high-value chemicals using solar energy has been a long sought-after goal. This project aims to create an integrated photoreactor and membrane separation system for efficient photocatalytic water splitting. The integrated system will efficiently produce hydrogen and ultrapure hydrogen peroxide, a critical and costly reagent used in the semiconductor and solar panel man ....Integrated solar to chemical production and membrane concentration system. The efficient conversion of low-cost raw materials to high-value chemicals using solar energy has been a long sought-after goal. This project aims to create an integrated photoreactor and membrane separation system for efficient photocatalytic water splitting. The integrated system will efficiently produce hydrogen and ultrapure hydrogen peroxide, a critical and costly reagent used in the semiconductor and solar panel manufacturing industries. The integrated system addresses current challenges in the production of high-quality hydrogen peroxide and demonstrates a practical solar-to-chemical process with economic benefits. It also advances knowledge in the fields of nanomaterials engineering, photocatalytic devices, and membrane technology.Read moreRead less
Photoelectrode design for solar driven methane to methanol conversion. This project aims to achieve efficient photoelectrocatalytic partial oxidation of greenhouse gas methane for methanol production with high selectivity. The program will design new semiconductor materials through rational defect engineering and co-catalyst selection to revolutionise methane conversion. The expected outcomes include sustainable processes to convert methane into valuable liquid chemicals like methanol, and compr ....Photoelectrode design for solar driven methane to methanol conversion. This project aims to achieve efficient photoelectrocatalytic partial oxidation of greenhouse gas methane for methanol production with high selectivity. The program will design new semiconductor materials through rational defect engineering and co-catalyst selection to revolutionise methane conversion. The expected outcomes include sustainable processes to convert methane into valuable liquid chemicals like methanol, and comprehensive understanding on functional material design for solar driven catalytic reactions. The significant benefits will include revolutionary methane mitigation technologies and sustainable processes for value-added chemical production, alleviating key environmental and energy challenges facing Australia and the world.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC230100042
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Training Centre for Battery Recycling. This Training Centre aims to transform Australia’s battery and resource industry by building advanced manufacturing capability for recycling mixed battery materials, promoting 2nd-life re-use, redesigning high performance batteries towards a battery circular economy, and advancing the supporting regulatory landscape. The research will address the challenges associated with battery recycling, deliver industrial demonstrations and promotion policies, and ....ARC Training Centre for Battery Recycling. This Training Centre aims to transform Australia’s battery and resource industry by building advanced manufacturing capability for recycling mixed battery materials, promoting 2nd-life re-use, redesigning high performance batteries towards a battery circular economy, and advancing the supporting regulatory landscape. The research will address the challenges associated with battery recycling, deliver industrial demonstrations and promotion policies, and create a dynamic skilled workforce. Outcomes are expected to shape a distinctive battery recycling model that shifts Australia to zero battery waste to landfill; establish a profitable and self-sustaining onshore industry chain; and help ensure the future of Australia’s energy security.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
Solar driven methane conversion for green methanol production. This project aims to develop advanced photoelectrode materials for solar driven methane partial oxidation to produce methanol. The key concepts are to develop new semiconductor devices and alloy metal cocatalysts in solving the slow charge and mass transfer challenges in catalytic methane partial oxidation reactions. The expected outcomes include ground-breaking approaches for catalytic materials design, efficient solar fuel producti ....Solar driven methane conversion for green methanol production. This project aims to develop advanced photoelectrode materials for solar driven methane partial oxidation to produce methanol. The key concepts are to develop new semiconductor devices and alloy metal cocatalysts in solving the slow charge and mass transfer challenges in catalytic methane partial oxidation reactions. The expected outcomes include ground-breaking approaches for catalytic materials design, efficient solar fuel production and cutting-edge knowledge on methane activation mechanism. The program is aligned with Australia’s Net-Zero Emission 2050 target, representing an innovative pathway in converting greenhouse gases into valuable chemicals, which will bring environmental and economic benefits to Australia.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
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: DE240101170
Funder
Australian Research Council
Funding Amount
$458,237.00
Summary
Design new-generation microscale thermoelectric device. This project aims at realizing ultrahigh thermoelectric power generating performance in the microscale device by developing new theoretical models for thermoelectric power-generation to guide the synergistic thin-film material and device design, and corresponding fabrication. The outcomes are expected to lead to revolutionary development of the thermoelectric technology, significantly extend the application of this emission/vibration/noise/ ....Design new-generation microscale thermoelectric device. This project aims at realizing ultrahigh thermoelectric power generating performance in the microscale device by developing new theoretical models for thermoelectric power-generation to guide the synergistic thin-film material and device design, and corresponding fabrication. The outcomes are expected to lead to revolutionary development of the thermoelectric technology, significantly extend the application of this emission/vibration/noise/service-free technology and expand the corresponding market, which will benefit the wide Australian community academically, educationally, socially, economically and environmentally.Read moreRead less
Energy-efficient liquid-flow system for electroreduction of carbon dioxide. Concerns about fossil fuel depletion and rising carbon emissions have brought about an urgent demand for carbon dioxide (CO2) capture and utilisation technologies. Facilitated by the mechanism-driven catalyst development and engineering innovation, this project aims to deliver a durable and cost-effective approach to electrochemical transformation of CO2 into the valuable products. The proposed automatic liquid-flow reac ....Energy-efficient liquid-flow system for electroreduction of carbon dioxide. Concerns about fossil fuel depletion and rising carbon emissions have brought about an urgent demand for carbon dioxide (CO2) capture and utilisation technologies. Facilitated by the mechanism-driven catalyst development and engineering innovation, this project aims to deliver a durable and cost-effective approach to electrochemical transformation of CO2 into the valuable products. The proposed automatic liquid-flow reactor system is expected to enable an energy efficient and practical viable CO2 reduction in benign aqueous electrolytes. The resulting innovations will not only reduce the environmental impact of atmospheric CO2 but also generate highly concentrated industrial feedstocks for the sustainable production of commodity chemicals.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