Development of next-generation nanoengineered advanced materials for targeted applications. This proposal seeks to develop and use a novel next-generation nanoscale fabrication technique to assemble technologically advanced materials not accessible via current fabrication strategies. The resulting materials are expected to find application in water purification, pharmaceutical development and drug delivery.
Functional Renewable Plastics: Developing Novel Polysaccharide, Protein and Natural Polyester Based Polymer Nanocomposites. Biopolymer based plastics (eg starch and proteins from plants; polylactic acid from wastes) are made from renewable sources and are readily biodegradable, making them good substitutes for synthetic plastics for uses like packaging and agricultural film.
Some biopolymer plastics properties (eg water migration barrier, strength) are not as high as synthetic plastics. Creat ....Functional Renewable Plastics: Developing Novel Polysaccharide, Protein and Natural Polyester Based Polymer Nanocomposites. Biopolymer based plastics (eg starch and proteins from plants; polylactic acid from wastes) are made from renewable sources and are readily biodegradable, making them good substitutes for synthetic plastics for uses like packaging and agricultural film.
Some biopolymer plastics properties (eg water migration barrier, strength) are not as high as synthetic plastics. Creating nano-biocomposites (biopolymer plastics mixed with low levels of nano particles) will improve the properties of biopolymer plastics, giving novel materials that can be substituted for synthetic plastics in a wider range of applications.
These products will reduce our environmental impact, and also create economic benefits from novel, high-value nano-biocomposites.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0454249
Funder
Australian Research Council
Funding Amount
$157,004.00
Summary
Specialist Analysis Facility for the Development of New Nanotechnologies. Nanotechnology is a developing technology with a limited number of academic research groups working in this field. Advanced infrastructure is requested for the characterisation and analysis of novel polymers, nanomaterials and biomaterials. The specialist applications herein demand both characterisation and processing control at the nanoscopic level and will greatly enhance teaching and core research capability within Fl ....Specialist Analysis Facility for the Development of New Nanotechnologies. Nanotechnology is a developing technology with a limited number of academic research groups working in this field. Advanced infrastructure is requested for the characterisation and analysis of novel polymers, nanomaterials and biomaterials. The specialist applications herein demand both characterisation and processing control at the nanoscopic level and will greatly enhance teaching and core research capability within Flinders University and the University of South Australia. This equipment will allow the universities to carry out this research in a unique manner. Other researchers cannot offer the synergy of synthesis, processing and characterisation of nanomaterials and biomaterials as described in this project.Read moreRead less
Supercritical CO2: A Clean, Green Reaction Medium for Novel Polymer Synthesis and Modification. This project will lead to the development of new macromolecular structures with application in many areas ranging from drug delivery to the microelectronics industry. More importantly, the processes used to manufacture these products will utilise supercritical CO2 - a clean, green processing technology that can totally remove the need for using environmentally-degrading, volatile organic solvents. The ....Supercritical CO2: A Clean, Green Reaction Medium for Novel Polymer Synthesis and Modification. This project will lead to the development of new macromolecular structures with application in many areas ranging from drug delivery to the microelectronics industry. More importantly, the processes used to manufacture these products will utilise supercritical CO2 - a clean, green processing technology that can totally remove the need for using environmentally-degrading, volatile organic solvents. The unique properties of scCO2 will be used to develop new polymer materials and processes. This technology will promote Australia's commitment towards greener industrial alternatives, while simultaneously strengthening our science and opening up new possibilities in the rapidly advancing area of nano-technology. Read moreRead less
Heterogeneous hydrophilic catalysts for green oxidation in bio-refining. The project aims to address one significant global challenge of developing green processes for producing high value chemicals from biomass, to enhance the environmental performance and cost-efficiency of bio-refining. This project aims to develop a new class of heterogeneous nanocatalysts with hydrophilic Co (salen) complexes for biomass oxidation in water rather than toxic solvent. This project will use this to devise prac ....Heterogeneous hydrophilic catalysts for green oxidation in bio-refining. The project aims to address one significant global challenge of developing green processes for producing high value chemicals from biomass, to enhance the environmental performance and cost-efficiency of bio-refining. This project aims to develop a new class of heterogeneous nanocatalysts with hydrophilic Co (salen) complexes for biomass oxidation in water rather than toxic solvent. This project will use this to devise practical routes for the production of targeted industrial components for flavours, fragrances, fine chemicals, and petrochemicals. The development of heterogeneous hydrophilic catalysts by which they will oxidise hydrophilic biomasses in a continuous flow system will dramatically improve the sustainability of the chemical industry.Read moreRead less
Electrowetting as a tool for measuring the surface energy of solids. Ionic liquids can be forced to spread over hydrophobic surfaces by applying an electric field, thus overwriting their natural tendency to bead. This phenomenon, called electrowetting, can be used to manipulate liquids but also to determine the surface energy of the solid surface which is a key design parameter in many applications.