Discovery Early Career Researcher Award - Grant ID: DE220100427
Funder
Australian Research Council
Funding Amount
$446,000.00
Summary
Engineered multifunctional membranes for aqueous organic redox flow battery. This project aims to develop multifunctional membranes with high ion conductivity and selectivity and high energy density to address the key challenges in the development of aqueous organic redox flow battery for renewable energy storage. The project will develop novel methodologies for precisely tuning and functionalising microporous materials to achieve cost-effective and scalable fabrication of membranes with multi-f ....Engineered multifunctional membranes for aqueous organic redox flow battery. This project aims to develop multifunctional membranes with high ion conductivity and selectivity and high energy density to address the key challenges in the development of aqueous organic redox flow battery for renewable energy storage. The project will develop novel methodologies for precisely tuning and functionalising microporous materials to achieve cost-effective and scalable fabrication of membranes with multi-functions, thus improving the energy efficiency and retaining the cycling capacity of redox flow batteries. The advancement of multifunctional membranes will enhance the efficiency of storage of intermittent and fluctuating renewable resources, thereby contributing to the reduction of carbon footprint in Australia. Read moreRead less
Australian Laureate Fellowships - Grant ID: FL180100029
Funder
Australian Research Council
Funding Amount
$2,545,000.00
Summary
Nanoionics: Engineering ion transport with two-dimensional materials. This project aims to use graphene and other emerging two-dimensional materials to investigate and manipulate ion transport in nanoscale channels. Nanoionics focuses on understanding ions for transport and storage in nanoscale systems, central to numerous technologies related to water, energy and biomedicine. The project will provide sophisticated methods for revolutionary technological innovations to solve problems in several ....Nanoionics: Engineering ion transport with two-dimensional materials. This project aims to use graphene and other emerging two-dimensional materials to investigate and manipulate ion transport in nanoscale channels. Nanoionics focuses on understanding ions for transport and storage in nanoscale systems, central to numerous technologies related to water, energy and biomedicine. The project will provide sophisticated methods for revolutionary technological innovations to solve problems in several industries including manufacturing, mining, water management and bioengineering. Providing access to previously unavailable structures and materials, the project will support Australia’s manufacturing sector by transforming established industries with next generation technologies. The project will also build capacity of nanoionics engineers and provide intellectual property for commercialised products.Read moreRead less
Development of advanced ceramic membranes: a robust solution to sustainable water treatment. Australia is one of the driest nations on Earth. While available fresh water supplies dwindle, options to treat 'used' water for reuse are gaining rapid popularity. Membranes are now state-of-the-art for water treatment, including all new desalination plants, but as they are polymeric based, they must be routinely cleaned with chemicals and replaced. The outcomes of this research will demonstrate innovat ....Development of advanced ceramic membranes: a robust solution to sustainable water treatment. Australia is one of the driest nations on Earth. While available fresh water supplies dwindle, options to treat 'used' water for reuse are gaining rapid popularity. Membranes are now state-of-the-art for water treatment, including all new desalination plants, but as they are polymeric based, they must be routinely cleaned with chemicals and replaced. The outcomes of this research will demonstrate innovative functional ceramic membranes which last longer and have lower requirement for cleaning chemicals and expert maintenance. This, in turn, will deliver water at lower cost and reduced environmental burden (chemical and membrane disposal), giving industry more sustainable solutions to treat water, which has now become an essential practice in society.Read moreRead less
Mapping, modelling, and manipulating graphene oxide interfaces. This project aims to provide a platform for the controllable manipulation of graphene oxide in water and with additives. Graphene oxide-based materials promise transformative change in the areas of filtration, separation science, energy materials and specialty coatings. Expansion of these materials into this broad range of high-performance applications is limited by the lack of reliable control over the organisation of the graphene ....Mapping, modelling, and manipulating graphene oxide interfaces. This project aims to provide a platform for the controllable manipulation of graphene oxide in water and with additives. Graphene oxide-based materials promise transformative change in the areas of filtration, separation science, energy materials and specialty coatings. Expansion of these materials into this broad range of high-performance applications is limited by the lack of reliable control over the organisation of the graphene oxide sheets in solution and in the presence of additives. This project will identify the practical steps for controlling the inter-sheet spacing in graphene oxide stacks, which is critical to realising their potential in real-world applications such as in filtration membranes for water desalination. This project will provide significant benefits in making reliable energy materials and filtration and separation membranes.Read moreRead less
Crystal engineering of membranes for chiral separation . This project addresses the urgent challenge of chiral separation in the manufacturing of pharmaceuticals and agrochemicals by creating a new class of membranes produced by engineering functionalised porous framework crystals. This project expects to generate new knowledge regarding how membrane chemistry and architecture can be used to achieve highly selective, fast chiral molecule transport. The expected outcomes of the project include ne ....Crystal engineering of membranes for chiral separation . This project addresses the urgent challenge of chiral separation in the manufacturing of pharmaceuticals and agrochemicals by creating a new class of membranes produced by engineering functionalised porous framework crystals. This project expects to generate new knowledge regarding how membrane chemistry and architecture can be used to achieve highly selective, fast chiral molecule transport. The expected outcomes of the project include new membrane compositions, design principles, fabrication techniques, and proof-of-concept production of scalable, high-performance composite membranes. This project should produce significant economic and environmental benefits in the development of advanced membranes, pharmaceuticals, and agrochemicals.Read moreRead less
Carbon nanotube fluidic channels for desalination - interplay of nanoscale confinement and electrostatics. Tiny tubes of carbon, ten thousand times smaller than human hair, allow water to pass through at extraordinary speed. This project aims to understand and improve their salt rejection properties using comprehensive experimental and theoretical approaches. This will provide the impetus and knowledge for developing advanced membranes for desalination
Smart Polymer Hydrogels for Simultaneous Waste Heat Utilisation and Wastewater Treatment for Sustainable Manufacturing. This project aims to develop dual-functionality, temperature-responsive polymer hydrogels as draw agents for continuous, forward osmosis wastewater treatment processes. It intends to use low–and-medium temperature waste heat as a green input into the process and thus significantly reduce the costs of wastewater treatment, and fresh water consumption, whilst effectively utilisin ....Smart Polymer Hydrogels for Simultaneous Waste Heat Utilisation and Wastewater Treatment for Sustainable Manufacturing. This project aims to develop dual-functionality, temperature-responsive polymer hydrogels as draw agents for continuous, forward osmosis wastewater treatment processes. It intends to use low–and-medium temperature waste heat as a green input into the process and thus significantly reduce the costs of wastewater treatment, and fresh water consumption, whilst effectively utilising waste heat generated in the manufacturing industry. The outcomes of this research aim to provide a unique opportunity for Australian researchers to become world leaders in the rapidly-emerging, energy-efficient forward osmosis technology which is very relevant not only to wastewater treatment, but also to desalination.Read moreRead less
Tailoring the nanoporous structure of polymer membranes for fast water permeation. A novel strategy of using a hydrophobic, charged polymer as an additive is proposed to tailor the wettability and charge density gradients in nanoporous polymer membranes for enhancing water permeation. The experimental results obtained in this project will advance our fundamental understanding of the roles of the pore surface charge and wettability gradients in water transport through nanopores. The proposed rese ....Tailoring the nanoporous structure of polymer membranes for fast water permeation. A novel strategy of using a hydrophobic, charged polymer as an additive is proposed to tailor the wettability and charge density gradients in nanoporous polymer membranes for enhancing water permeation. The experimental results obtained in this project will advance our fundamental understanding of the roles of the pore surface charge and wettability gradients in water transport through nanopores. The proposed research is expected to result in a major breakthrough in designing nanoporous membranes with ultrahigh high flux and superior separation properties for a variety of applications including water treatment and food processing. Read moreRead less
Non-polyamide-based polymer membranes for efficient water processing. This project aims to develop an innovative, two-dimensional nanosheet scaffold polymerisation technique for the fabrication of advanced membranes. Membrane technology plays a key role in wastewater treatment and water desalination and purification. However, current membranes are not stable in an oxidation environment such as chlorine, which leads to significant membrane replacement costs. Through the development of new membran ....Non-polyamide-based polymer membranes for efficient water processing. This project aims to develop an innovative, two-dimensional nanosheet scaffold polymerisation technique for the fabrication of advanced membranes. Membrane technology plays a key role in wastewater treatment and water desalination and purification. However, current membranes are not stable in an oxidation environment such as chlorine, which leads to significant membrane replacement costs. Through the development of new membrane fabrication technology the project aims to produce non-polyamide-based polymer membranes with outstanding oxidation tolerance and separation properties. This will potentially simplify membrane processes, and improve water processing efficiency in wastewater treatment for power generation, and clean drinking water production.
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Structurally-bridged crystalline molecular sieve-polymer membranes. This project aims to produce a membrane platform technology for efficient and cost-effective separation in natural gas processing and petrochemicals, using crystalline sieve materials. It will address the mismatch of mechanical properties between crystalline molecular sieve materials (zeolites and metal organic frameworks) and polymers, and coating flaws which limit their use as gas separation membranes. It will create nano-rein ....Structurally-bridged crystalline molecular sieve-polymer membranes. This project aims to produce a membrane platform technology for efficient and cost-effective separation in natural gas processing and petrochemicals, using crystalline sieve materials. It will address the mismatch of mechanical properties between crystalline molecular sieve materials (zeolites and metal organic frameworks) and polymers, and coating flaws which limit their use as gas separation membranes. It will create nano-reinforcement in the coating and polymer substrate, with nano-bridges between them. The resulting membranes will be mechanically tough and separate better than existing membranes. Advanced membranes are expected to benefit fuel industries by reducing separation cost and energy consumption.Read moreRead less