Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347258
Funder
Australian Research Council
Funding Amount
$170,000.00
Summary
Polymer Analysis Facility. The aim of this application is to establish a facility for polymer analysis. The infra-red spectrometer will be used primarily for analysis of polymerisation reactions whilst the thermal analysis equipment is essential for the characterisation of polymers and thin polymer coatings. The facility will contribute an essential analysis capability for three strong research groups who work in different aspects of polymer science. The main outcomes will improved productivity ....Polymer Analysis Facility. The aim of this application is to establish a facility for polymer analysis. The infra-red spectrometer will be used primarily for analysis of polymerisation reactions whilst the thermal analysis equipment is essential for the characterisation of polymers and thin polymer coatings. The facility will contribute an essential analysis capability for three strong research groups who work in different aspects of polymer science. The main outcomes will improved productivity within the current projects together with new collaborations, particularly between the Steel Institute (ISPP) at Wollongong and the Centre of Advanced Molecular Design (CAMD) at UNSW.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347346
Funder
Australian Research Council
Funding Amount
$210,000.00
Summary
Electrochemical Atomic Force Microscope and Nano-Manipulation Facility. This new Facility will add the nano-dimension to the excellent electrochemical mapping facility established at the University of Wollongong over the past 2 years. The instrument we propose to install will allow us to probe electrochemical events and, in particular, the influence of these events on the structure of customised materials at the nano level. This new capability will impact on our research into the development o ....Electrochemical Atomic Force Microscope and Nano-Manipulation Facility. This new Facility will add the nano-dimension to the excellent electrochemical mapping facility established at the University of Wollongong over the past 2 years. The instrument we propose to install will allow us to probe electrochemical events and, in particular, the influence of these events on the structure of customised materials at the nano level. This new capability will impact on our research into the development of efficient artificial muscles, biosensors, corrosion protection coatings, polymeric photovoltaics and new surfaces for mammalian cell culturing.Read moreRead less
Polymers for Novel Surfactants. The aim of the proposed research is to develop novel surface-active polymers with complex architectures and more efficient strategies for the synthesis of surface-active polymers in general. We will exploit the polymerization characteristics of the novel catalytic chain transfer and radical addition-fragmentation transfer polymerization techniques to achieve polymerization control that has been virtually impossible hitherto. The proposed research will thus make ....Polymers for Novel Surfactants. The aim of the proposed research is to develop novel surface-active polymers with complex architectures and more efficient strategies for the synthesis of surface-active polymers in general. We will exploit the polymerization characteristics of the novel catalytic chain transfer and radical addition-fragmentation transfer polymerization techniques to achieve polymerization control that has been virtually impossible hitherto. The proposed research will thus make accessible a wide range of novel surface-active polymers that have been impossible to synthesise to date, and which we expect to be more efficient and hence leads to greener technologies.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453637
Funder
Australian Research Council
Funding Amount
$256,804.00
Summary
Multi-dimensional polymer characterization facility. The microstructure of polymers dominates their physical properties. This integrated facility will create a world-leading means of characterizing in multiple dimensions the microstructure of complex polymers, eg copolymers and branched polymers. The facility will yield information on the distributions of chain end-groups, monomer microstructure, and branches, as functions of molecular weight. The facility will provide otherwise unobtainable dat ....Multi-dimensional polymer characterization facility. The microstructure of polymers dominates their physical properties. This integrated facility will create a world-leading means of characterizing in multiple dimensions the microstructure of complex polymers, eg copolymers and branched polymers. The facility will yield information on the distributions of chain end-groups, monomer microstructure, and branches, as functions of molecular weight. The facility will provide otherwise unobtainable data for a set of projects exploring questions ranging from how new synthetic materials with tailor-made properties can be created, through to how our understanding of natural polymers can be advanced to improve crop utilization.Read moreRead less
Novel Complex Architecture Polymers via a Combination of RAFT Chemistry and Pericyclic Reactions: Synthesis and Characterization. The project aims at advancing the synthetic limits and broadening the synthetic scope of living free radical polymerization and thus enhancing the library of polymer structures available for applications ranging from drug delivery to opto-electronics. Current material design for these applications is yet to reach its full potential through innovative synthetic approac ....Novel Complex Architecture Polymers via a Combination of RAFT Chemistry and Pericyclic Reactions: Synthesis and Characterization. The project aims at advancing the synthetic limits and broadening the synthetic scope of living free radical polymerization and thus enhancing the library of polymer structures available for applications ranging from drug delivery to opto-electronics. Current material design for these applications is yet to reach its full potential through innovative synthetic approaches. The proposal critically underpins and further advances Australia's leading position in both breakthrough science as well as advanced materials. Due to its significant scientific breadth and large coverage of both synthetic and physical aspects of polymer science, the project also provides a significant platform for research training at both honours and PhD level.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560981
Funder
Australian Research Council
Funding Amount
$160,940.00
Summary
Confronting the Challenges in Modern Spectroscopy of Polymers. Polymers and nanocomposites are increasingly being used in new, high value applications as diverse as medicine, structural engineering, optics and electronics. In order to control and understand polymer performance, a detailed knowledge of the chemical structure at all stages in their lifecycle is required - in the liquid, rubber and solid states and during degradation. This application seeks to establish a coordinated Polymer Spectr ....Confronting the Challenges in Modern Spectroscopy of Polymers. Polymers and nanocomposites are increasingly being used in new, high value applications as diverse as medicine, structural engineering, optics and electronics. In order to control and understand polymer performance, a detailed knowledge of the chemical structure at all stages in their lifecycle is required - in the liquid, rubber and solid states and during degradation. This application seeks to establish a coordinated Polymer Spectroscopy Network using new forms of infrared and NMR spectroscopy to probe samples (usually of an non-planar geometry) in a range of configurations. These will be used simultaneously with other techniques such as rheology or thermogravimetry, and will produce capabilities unique in Australia.Read moreRead less
Manipulating the self-assembly properties of fungal hydrophobin proteins for the design of novel biological polymers. Hydrophobin-based products will be novel biocompatible and biodegradable products with applications in the fields of medical implants, biosensors, detergents, coatings and pharmaceutical and industrial emulsions. They have the potential to directly improve the lives of all Australians and to be of benefit to the Australian economy and environment. This collaborative research pro ....Manipulating the self-assembly properties of fungal hydrophobin proteins for the design of novel biological polymers. Hydrophobin-based products will be novel biocompatible and biodegradable products with applications in the fields of medical implants, biosensors, detergents, coatings and pharmaceutical and industrial emulsions. They have the potential to directly improve the lives of all Australians and to be of benefit to the Australian economy and environment. This collaborative research project will enable Australian scientists to gain from working with a multinational company and to acquire skills in the rapidly expanding fields of structural and molecular biology. The University of Sydney will own any intellectual property arising from this work and will benefit from the commercialisation of hydrophobin-based products.Read moreRead less
Establishing In-Depth Understanding of Molecular Degradation Processes in Acrylic Based Polymer Coil-Coatings for Domestic Roofing Applications. The national benefit is multipronged: (i) BlueScope Steel will maintain its technology leadership through continued innovation by taking advantage of the scientific insights that the project delivers for the introduction of next generation long lasting coil coatings for steel, based on an environmentally friendly production processes. (ii) The applicati ....Establishing In-Depth Understanding of Molecular Degradation Processes in Acrylic Based Polymer Coil-Coatings for Domestic Roofing Applications. The national benefit is multipronged: (i) BlueScope Steel will maintain its technology leadership through continued innovation by taking advantage of the scientific insights that the project delivers for the introduction of next generation long lasting coil coatings for steel, based on an environmentally friendly production processes. (ii) The application of mass spectrometry for the analysis of polymer degradation has been pioneered by the CI and BlueScope Steel. The project will demonstrate the power of this technique and secure Australia's place at the forefront of molecular polymer degradation research. (iii) The project has a strong educational component, training a PhD student at the interface of application and fundamental research.Read moreRead less
Fundamentals of the Performance Chemistry of Water-borne Acrylic Polymer based Surface Coatings for Pre-painted Steel Employed in Domestic Roofing Applications. The proposed project will systematically investigate the structure-performance relationships of acrylic emulsion based surface coatings and provide a detailed understanding of their degradation mechanisms. The improved understanding of these coatings will lead to the development of an optimum coating for steel roofs with extremely high d ....Fundamentals of the Performance Chemistry of Water-borne Acrylic Polymer based Surface Coatings for Pre-painted Steel Employed in Domestic Roofing Applications. The proposed project will systematically investigate the structure-performance relationships of acrylic emulsion based surface coatings and provide a detailed understanding of their degradation mechanisms. The improved understanding of these coatings will lead to the development of an optimum coating for steel roofs with extremely high durability and resistance against degradation and gloss loss in typical tropical and sub-tropical Australian climates.Read moreRead less
Polymer nanoobjects functionalized by polymer brushes: preparation, organization and integration in devices. The proposed project targets the collaboration between two leading research teams. The University of Marburg is leading in the area of the preparation of nanoobjects, while the research team at CAMD (UNSW) focuses on the preparation of well-controlled polymer structures via RAFT polymerisation. The combined strength of both groups seeks to improve the properties of nanodevices by the atta ....Polymer nanoobjects functionalized by polymer brushes: preparation, organization and integration in devices. The proposed project targets the collaboration between two leading research teams. The University of Marburg is leading in the area of the preparation of nanoobjects, while the research team at CAMD (UNSW) focuses on the preparation of well-controlled polymer structures via RAFT polymerisation. The combined strength of both groups seeks to improve the properties of nanodevices by the attachment of well-defined polymer layers. We expect therefore an optimum scientific output with both groups focusing on their research potency next to being able to access new knowledge. The visit to the German research group enables the Australian researchers access to a leading team in nanotechnology.Read moreRead less