Order from chaos: Rational design of biointerfacing plasma polymer coatings. The project goal is to facilitate a new generation of bio-interface platforms to be designed using plasma processing. Functionalised plasma polymer surfaces used for bio-interfaces result from random processes in the plasma phase and at the surface. While rules-of-thumb exist for tailoring simple functionalised plasma polymers, detailed knowledge linking plasma processes to surface chemistry is lacking. Using a homologo ....Order from chaos: Rational design of biointerfacing plasma polymer coatings. The project goal is to facilitate a new generation of bio-interface platforms to be designed using plasma processing. Functionalised plasma polymer surfaces used for bio-interfaces result from random processes in the plasma phase and at the surface. While rules-of-thumb exist for tailoring simple functionalised plasma polymers, detailed knowledge linking plasma processes to surface chemistry is lacking. Using a homologous series of precursors, the project aims to unravel physical and chemical plasma processes to enable retention of complex surface functional groups which are critical for subsequent surface processing. This is designed to be achieved by linking plasma physics and chemistry via plasma phase mass spectrometry and surface analysis.Read moreRead less
Nanoparticle driven templating of microspheres as chromatographic materials. This project aims to pioneer a novel, high-performing class of nano-patterned core-shell particles as chromatographic materials. It will use advanced polymerization and particle preparation techniques in combination with degradable nanoparticles design, to enable the plug-and-play assembly of chromatographic columns. Size-exclusion chromatography (SEC) is one of the most important analytical techniques for polymer chem ....Nanoparticle driven templating of microspheres as chromatographic materials. This project aims to pioneer a novel, high-performing class of nano-patterned core-shell particles as chromatographic materials. It will use advanced polymerization and particle preparation techniques in combination with degradable nanoparticles design, to enable the plug-and-play assembly of chromatographic columns. Size-exclusion chromatography (SEC) is one of the most important analytical techniques for polymer chemistry. The expected outcomes of this project are faster measurement times and the possibility of imaging molecular weight distributions at a new level of detail. This project could place Australia at the cutting edge of size-exclusion chromatography phase design in partnership with a leading manufacturer of stationary phases.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100090
Funder
Australian Research Council
Funding Amount
$1,136,244.00
Summary
Xe-plasma dual beam for advanced future materials. This project aims to establish a state of the art Xe-Plasma dual-beam facility providing characterisation and fabrication capabilities to Australia’s research community. The project will use two beams - one Xe, the other electrons - to mill the surface of bulk materials which are subsequently analysed by electron or ion beam techniques to determine atomic-scale microstructure(s) and compositions. Anticipated outcomes are advanced materials engin ....Xe-plasma dual beam for advanced future materials. This project aims to establish a state of the art Xe-Plasma dual-beam facility providing characterisation and fabrication capabilities to Australia’s research community. The project will use two beams - one Xe, the other electrons - to mill the surface of bulk materials which are subsequently analysed by electron or ion beam techniques to determine atomic-scale microstructure(s) and compositions. Anticipated outcomes are advanced materials engineering and new knowledge about ancient and future materials. This is expected to provide significant advances across a variety of fields including material science, engineering and geology and enhance trans-disciplinary collaborations.Read moreRead less
Advanced Fibre Interfaces in Active Water Management Systems. Flooding is a critical issue in Australia, generating considerable economic losses, including by stormwater contamination. The current project will pioneer an integrated solution for stormwater retention, while removing chemical pollutants. In collaboration with the company ROCKWOOL-Lapinus - based on a stonewool fibre platform - we will (i) design fibre coatings based on a versatile and chemically simple deposition process, (ii) inco ....Advanced Fibre Interfaces in Active Water Management Systems. Flooding is a critical issue in Australia, generating considerable economic losses, including by stormwater contamination. The current project will pioneer an integrated solution for stormwater retention, while removing chemical pollutants. In collaboration with the company ROCKWOOL-Lapinus - based on a stonewool fibre platform - we will (i) design fibre coatings based on a versatile and chemically simple deposition process, (ii) incorporate functionalities onto the fibres allowing active stormwater treatment to e.g. retain pollutants or target heavy metals and (iii) investigate these interfaces in-depth by advanced surface and interface characterisation methods to understand the fibre interface properties from nano- to macroscale.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101788
Funder
Australian Research Council
Funding Amount
$415,498.00
Summary
Advanced Macromolecular Architecture via Selenium. The overarching aim of this project is to drastically expand the scale and scope of selenium-based macromolecular chemistry via safe, odor-free multicomponent reactions utilising elemental selenium. This project will develop new methods and techniques in drastically reducing the cost while increasing worker and environmental safety of industrial elastomers such as Spandex. Next the project will exploit selenium's sensitivity to ozonolysis to des ....Advanced Macromolecular Architecture via Selenium. The overarching aim of this project is to drastically expand the scale and scope of selenium-based macromolecular chemistry via safe, odor-free multicomponent reactions utilising elemental selenium. This project will develop new methods and techniques in drastically reducing the cost while increasing worker and environmental safety of industrial elastomers such as Spandex. Next the project will exploit selenium's sensitivity to ozonolysis to design a new instrument capable of extreme precision in monitoring oxidative damage in polymeric materials. Finally, selenium's unique reactivity will lend itself towards the next generation of smart materials which will be capable of completely reorganizing their structure down to the molecular level.Read moreRead less
On-demand visible light degradable dental materials. This project aims to break new ground in the field of advanced adhesives by pioneering a unique system that can be cleaved with a defined visible light trigger, enabling the removal of previously bonded material without mechanical force. This would allow two materials to be strongly bonded, including dental crowns, braces and implants. The project will advance on-demand degradable materials design, introducing an advanced class of responsive n ....On-demand visible light degradable dental materials. This project aims to break new ground in the field of advanced adhesives by pioneering a unique system that can be cleaved with a defined visible light trigger, enabling the removal of previously bonded material without mechanical force. This would allow two materials to be strongly bonded, including dental crowns, braces and implants. The project will advance on-demand degradable materials design, introducing an advanced class of responsive networks for applications where reversible bonding is critical. It will have flow on benefits in future dental material applications and also have applications where simple-to-remove, temporary adhesives are required.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100148
Funder
Australian Research Council
Funding Amount
$1,350,000.00
Summary
Advanced Nuclear Magnetic Resonance Technologies for Southeast Queensland. This project aims to establish an advanced Nuclear Magnetic Resonance capability and capacity at two of Queenslands' leading research intensive universities. The project expects to enhance the scope and productivity of hundreds of research projects spanning natural products, synthetic, medicinal, materials and environmental science. Expected outcomes include smarter science, more productive collaborations and superior res ....Advanced Nuclear Magnetic Resonance Technologies for Southeast Queensland. This project aims to establish an advanced Nuclear Magnetic Resonance capability and capacity at two of Queenslands' leading research intensive universities. The project expects to enhance the scope and productivity of hundreds of research projects spanning natural products, synthetic, medicinal, materials and environmental science. Expected outcomes include smarter science, more productive collaborations and superior research training, leading to innovative solutions to challenging problems that confront science and society. This investment should provide significant benefits in the form of new knowledge across multiple disciplines, informing the design of future medicines, agrochemicals, materials and other products.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100141
Funder
Australian Research Council
Funding Amount
$310,000.00
Summary
High resolution nuclear magnetic resonance spectroscopy for glycomics, metabonomics and soft materials applications. This project will enhance the nuclear magnetic resonance spectroscopy capabilities and the world class research being undertaken at the Institute for Glycomics, Griffith University and Queensland University of Technology. This powerful technique can contribute information in diverse research areas such as glycomics, metabonomics and soft materials research.
Dyes and Pigments as Building Blocks for Novel High Performance Organic Semiconductors. Natural dyes and pigments are well known for their bright colours, photochemical and thermal stability, and cheap cost. Recently, the necessity of high performing materials in the organic electronics has stimulated a renaissance of these historical molecules and their subsequent derivatives into new families of ?-conjugated building blocks used to construct new donor-acceptor semiconductors. The aim of this p ....Dyes and Pigments as Building Blocks for Novel High Performance Organic Semiconductors. Natural dyes and pigments are well known for their bright colours, photochemical and thermal stability, and cheap cost. Recently, the necessity of high performing materials in the organic electronics has stimulated a renaissance of these historical molecules and their subsequent derivatives into new families of ?-conjugated building blocks used to construct new donor-acceptor semiconductors. The aim of this project is to explore various novel dyes, pigments and their derivatives for constructing outstanding materials for future organic electronics.Read moreRead less