Novel Synthesis and Bio-applications of Functional Macroporous Ordered Siliceous Foams. This project will lead to advances in materials science and nanotechnology, providing high efficiency separation and purification for viruses or plasmid deoxyribonucleic acid (DNA), which are important in modern gene engineering for the treatment of genetic and acquired diseases. Application benefits also include developing a new protocol in the detection of trace amount proteins, which will afford a signific ....Novel Synthesis and Bio-applications of Functional Macroporous Ordered Siliceous Foams. This project will lead to advances in materials science and nanotechnology, providing high efficiency separation and purification for viruses or plasmid deoxyribonucleic acid (DNA), which are important in modern gene engineering for the treatment of genetic and acquired diseases. Application benefits also include developing a new protocol in the detection of trace amount proteins, which will afford a significant improvement in diverse fields such as health care. Through this project, novel macroporous materials will be fabricated using an economically and environmentally sustainable approach. These new materials will have unique structures and properties compared to conventional macroporous materials, advancing Australia's intellectual position in this discipline.Read moreRead less
Production and nano-characterisation of II-VI semiconductor quantum dots from plant cell cultures. Nanocrystallites with semiconductor properties have potential applications in medicine, microelectronics and waste treatment. Cheap, reliable methods for producing large quantities of monodisperse nanoparticles are required. Solution techniques have been used most commonly; however, production of stable, high-quality particles remains difficult. Biological synthesis using plant cell culture offers ....Production and nano-characterisation of II-VI semiconductor quantum dots from plant cell cultures. Nanocrystallites with semiconductor properties have potential applications in medicine, microelectronics and waste treatment. Cheap, reliable methods for producing large quantities of monodisperse nanoparticles are required. Solution techniques have been used most commonly; however, production of stable, high-quality particles remains difficult. Biological synthesis using plant cell culture offers several important advantages. As peptide capping is incorporated into the biological assembly process, the nanoparticles are restricted in size, their stability is improved, and their surfaces are passivated. Application of plant cultures for nanocrystallite production is a novel approach with the potential to yield significant improvements in the quality of manufactured quantum dots.Read moreRead less
Gel interactions in geopolymers for sustainable construction. This project will benefit Australia by enabling reliable production of environmentally friendly construction materials. These materials, geopolymer cements, have been developed to the point where they are beginning to be commercialised in Australia, but the factors controlling their performance and durability are only beginning to be well understood. Geopolymer cements are made using ash from coal-fired power stations, and are competi ....Gel interactions in geopolymers for sustainable construction. This project will benefit Australia by enabling reliable production of environmentally friendly construction materials. These materials, geopolymer cements, have been developed to the point where they are beginning to be commercialised in Australia, but the factors controlling their performance and durability are only beginning to be well understood. Geopolymer cements are made using ash from coal-fired power stations, and are competitive with traditional Portland cement in terms of both performance and cost. This project will use recently developed experimental techniques and Australian research expertise in this field, and will lead to significant environmental and cost savings in the construction industry.Read moreRead less
Geopolymers for nuclear applications. With the pressing need for the reduction of Greenhouse emissions from electricity generation in Australia, one option that must be seriously considered is nuclear energy. However, the issue of waste storage is a highly significant one that must be addressed. Geopolymeric cements are expected to perform much better than traditional Portland cements in nuclear applications, both for solidification of radioactive wastes and also for the construction of undergro ....Geopolymers for nuclear applications. With the pressing need for the reduction of Greenhouse emissions from electricity generation in Australia, one option that must be seriously considered is nuclear energy. However, the issue of waste storage is a highly significant one that must be addressed. Geopolymeric cements are expected to perform much better than traditional Portland cements in nuclear applications, both for solidification of radioactive wastes and also for the construction of underground waste storage bunkers. This project will use Australia's strong existing knowledge in geopolymers research, and apply it to the development of materials to fill the need for environmentally secure waste storage solutions.Read moreRead less
Sustainable processes for next-generation surface coatings and core-shell nanoparticles based on biomolecular templating. Nanotechnology promises new materials with broad impact, yet our ability to manufacture complex nanomaterials using sustainable processes is very limited. This project will advance our knowledge of nanomaterial manufacture using inspiration from how complex materials are made in nature. This project will deliver next-generation surface coatings that are incredibly thin but st ....Sustainable processes for next-generation surface coatings and core-shell nanoparticles based on biomolecular templating. Nanotechnology promises new materials with broad impact, yet our ability to manufacture complex nanomaterials using sustainable processes is very limited. This project will advance our knowledge of nanomaterial manufacture using inspiration from how complex materials are made in nature. This project will deliver next-generation surface coatings that are incredibly thin but strong, and specialised nanoparticles made using biocompatible processes. The knowledge and methods developed will benefit the biotechnology and nanotechnology sectors, as well as research in soft-matter science, quantum computing, photonics and healthcare. The value proposition for innovation in these fields will increasingly rely on new nanomanufacturing approaches.Read moreRead less
Scale-up and Intelligent Control of Granulation Processes. Granulation is the process that forms granular products with carefully targeted properties from powdery or liquid feeds. Granular products abound in the pharmaceutical, agricultural & industrial chemicals, and food & consumer goods industries. Poor understanding of the granulation causes delays in the time to market of new products and poor efficiency in large scale continuous granulation plants. This project will build on recent adva ....Scale-up and Intelligent Control of Granulation Processes. Granulation is the process that forms granular products with carefully targeted properties from powdery or liquid feeds. Granular products abound in the pharmaceutical, agricultural & industrial chemicals, and food & consumer goods industries. Poor understanding of the granulation causes delays in the time to market of new products and poor efficiency in large scale continuous granulation plants. This project will build on recent advances in the understanding of granulation fundamentals to (1) develop new robust design and scale up rules (2) develop intelligent control schemes for continuous granulation circuits, and (3) develop a new generation of regime separated granulators. The project is receiving substantial support from 3 industry partners (MSD Australia, Incitec and WMC Fertilizers) with cash contributions over 40% of the ARC grant requested, as well as very substantial in-kind contributions.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0238492
Funder
Australian Research Council
Funding Amount
$139,000.00
Summary
State of Art Particle Size Analysers. Particulate materials are encountered in many different forms, sizes and environments, and vastly different areas such as biological, environmental, chemical and materials engineering. Particle size and its distribution are fundamental properties of these materials. Existing particle size measuring equipment in Australia is poor as currently available facilities cannot accurately resolve particle sizes in concentrated dispersions, nor can they visualise the ....State of Art Particle Size Analysers. Particulate materials are encountered in many different forms, sizes and environments, and vastly different areas such as biological, environmental, chemical and materials engineering. Particle size and its distribution are fundamental properties of these materials. Existing particle size measuring equipment in Australia is poor as currently available facilities cannot accurately resolve particle sizes in concentrated dispersions, nor can they visualise the in situ structure and size of fragile assemblies of particles (flocs). This proposal seeks funding for a suite of complementary particle size analysers, for use in an extensive number of research areas, to specifically address these critical current deficits.Read moreRead less