Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775548
Funder
Australian Research Council
Funding Amount
$180,000.00
Summary
Advanced characterisation facilities for functional nanostructured materials. A critical factor that enhances frontier research is a set of advanced core research experimental facilities for material characterisation purposes. The proposed equipment aims to: (1) provide research facilities for advanced nanomaterial research; (2) improve national competitiveness and growth in a knowledge-based economy; and (3) foster local talented researchers in order to meet the strategic needs of the nation fo ....Advanced characterisation facilities for functional nanostructured materials. A critical factor that enhances frontier research is a set of advanced core research experimental facilities for material characterisation purposes. The proposed equipment aims to: (1) provide research facilities for advanced nanomaterial research; (2) improve national competitiveness and growth in a knowledge-based economy; and (3) foster local talented researchers in order to meet the strategic needs of the nation for a sustainable environment. These activities will revitalise Australia's leading role in creating new technologies with particular relevance to using advanced nanostructures for the production of clean air and water, and sustainable energy alternatives.Read moreRead less
High performance conductive mesoporous carbon electrodes: a low energy desalination alternative. The high cost of existing desalination technology has limited its wider application. There is an urgent need for alternatives which require less energy than current methods. The proposed electrosorption process utilising porous carbon electrodes has the advantage of very low energy demand. Electrosorption therefore has the opportunity to become an alternative desalination option for application in a ....High performance conductive mesoporous carbon electrodes: a low energy desalination alternative. The high cost of existing desalination technology has limited its wider application. There is an urgent need for alternatives which require less energy than current methods. The proposed electrosorption process utilising porous carbon electrodes has the advantage of very low energy demand. Electrosorption therefore has the opportunity to become an alternative desalination option for application in a national and global water desalination market. Advancement in water desalination technology has the potential for a profound social, economical and environmental impact. This vital research is aligned with the National Research Priority 1, An Environmentally Sustainable Australia; Priority Goal: Water, A critical resource.Read moreRead less
New nanocomposites of porous materials and visible light sensitive TiO2 for efficient wastewater purification. The innovative newly proposed materials can trap and efficiently decompose dissolved organics in the same process, without generating any waste for disposal. No UV is required and the solar radiation can be efficiently used. The proposed research will be a significant breakthrough in the field of water treatment that reduces energy consumption, uses low cost materials and provides a rea ....New nanocomposites of porous materials and visible light sensitive TiO2 for efficient wastewater purification. The innovative newly proposed materials can trap and efficiently decompose dissolved organics in the same process, without generating any waste for disposal. No UV is required and the solar radiation can be efficiently used. The proposed research will be a significant breakthrough in the field of water treatment that reduces energy consumption, uses low cost materials and provides a real solution. The research findings will be useful to a wide spectrum of manufacturing industries which are currently generating slightly contaminated wastewater, and will be beneficial to the community in general. At the same time, the industries will be a step forward toward sustainable manufacturing.Read moreRead less
Photodesorption Phenomena and Photoreactive Nanosorbent Materials for Water and Wastewater Purification. Introducing more efficient production of drinking water and wastewater treatment methods for reuse is important to address increasing water scarcity in Australia. The proposed project will develop a water purification technology to remove pollutants using a recently discovered process. This process offers simple and affordable operation that is clean, robust and requires minimal attention. Th ....Photodesorption Phenomena and Photoreactive Nanosorbent Materials for Water and Wastewater Purification. Introducing more efficient production of drinking water and wastewater treatment methods for reuse is important to address increasing water scarcity in Australia. The proposed project will develop a water purification technology to remove pollutants using a recently discovered process. This process offers simple and affordable operation that is clean, robust and requires minimal attention. The technology is particularly suitable for small-scale applications in rural and remote areas, and has significant export potential. The project will strengthen established links between Australian and Korean research centres through the production of improved nanomaterials, and the development of the novel water purification technologyRead moreRead less
Zeolitic Nanoflake-Polymer Composite Membranes for Low Energy Desalination. The desalination of seawater is becoming an important source of drinking water for Australia. The current desalination process using polymer membranes is energy-intensive. The proposed project will contribute to the development of low energy desalination technology by advancing membrane design and fabrication techniques. The use of zeolitic nanoflake-polymer composite membranes developed in this project is expected to su ....Zeolitic Nanoflake-Polymer Composite Membranes for Low Energy Desalination. The desalination of seawater is becoming an important source of drinking water for Australia. The current desalination process using polymer membranes is energy-intensive. The proposed project will contribute to the development of low energy desalination technology by advancing membrane design and fabrication techniques. The use of zeolitic nanoflake-polymer composite membranes developed in this project is expected to substantially reduce energy consumption in the desalination process. This research will produce important economic and environmental benefits by developing a green technology for fresh water production and water treatment for power generation, irrigation and other industrial uses.Read moreRead less
Development of the thinnest possible, multifunctional DNA-nanoparticle membranes for ultrafast filtration and smart sensing. Development of ultrathin and multifunctional membranes is currently in urgent need to improve our technologies in energy, environment and healthcare. This project will apply innovative nanobiomaterials to build such membrane systems and establish the design rules and develop key technologies.
Quantification of airborne engineered nanoparticles: developing a scientific framework to inform their regulation and control. Despite the presence of airborne engineered nanoparticles in many commercial/research facilities, there are no established methods for their detection/characterisation. This work aims to develop a foundation for the quantitative assessment of airborne engineered nanoparticles, which is critical for controlling exposure and minimising health risks.
Detection, characteristics and dynamics of airborne engineered nanoparticles for human exposure assessment. Recent advances in nanotechnology have led to questions about the safety of airborne engineered nanoparticles in commercial and research facilities. This project aims to develop an understanding of nanoparticle emission and behaviour in the air, which is needed to control workplace exposure to these particles and minimise the risk to human health.
Discovery Early Career Researcher Award - Grant ID: DE150101617
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
Novel Three Dimensional Porous Boron Nitride Foam for Water Cleaning. This project aims to develop new three-dimensional (3D) porous nanomaterials of boron nitride (BN) foam with excellent sorption properties for water purification. New chemical synthesis approaches will be used to produce 3D porous BN foams with high porosity, large surface area and high mechanical stability leading to a high adsorption capacity, easy regeneration and excellent recycle ability for water purification. The expect ....Novel Three Dimensional Porous Boron Nitride Foam for Water Cleaning. This project aims to develop new three-dimensional (3D) porous nanomaterials of boron nitride (BN) foam with excellent sorption properties for water purification. New chemical synthesis approaches will be used to produce 3D porous BN foams with high porosity, large surface area and high mechanical stability leading to a high adsorption capacity, easy regeneration and excellent recycle ability for water purification. The expected outcomes include a new class of light absorbent materials, new production techniques and a high efficiency water cleaning technique.Read moreRead less
Engineered and functionalized nanocarbons for clean energy and water. This project aims to develop a novel material platform based on metal-free graphitic carbon nitride and its functionalised composites in solar energy utilisation for water treatment, energy conversion to hydrogen, solar cell, and electrochemical battery in energy storage. The project aims to address the scientific challenges in rational nanomaterial synthesis, functionalisation and practical applications. The research outcomes ....Engineered and functionalized nanocarbons for clean energy and water. This project aims to develop a novel material platform based on metal-free graphitic carbon nitride and its functionalised composites in solar energy utilisation for water treatment, energy conversion to hydrogen, solar cell, and electrochemical battery in energy storage. The project aims to address the scientific challenges in rational nanomaterial synthesis, functionalisation and practical applications. The research outcomes are expected to provide a scientific basis for development of cutting-edge nanotechnologies for sustainable energy transformation and wastewater treatment, leading to significant benefits in Australian energy industries and environment.Read moreRead less