Tailoring the microwave dielectric properties of promising electroceramics for use in wireless telecommunication components and devices. This project aims to develop and tailor the microwave dielectric properties of promising electroceramic materials specifically targeting next generation wireless telecommunications applications. The partnership between the ANU and the Australian company Microwave and Materials Designs has the potential to enable new microwave electroceramic materials to be disc ....Tailoring the microwave dielectric properties of promising electroceramics for use in wireless telecommunication components and devices. This project aims to develop and tailor the microwave dielectric properties of promising electroceramic materials specifically targeting next generation wireless telecommunications applications. The partnership between the ANU and the Australian company Microwave and Materials Designs has the potential to enable new microwave electroceramic materials to be discovered and then incorporated into new microwave components and/or devices developed in response to the requirements of the international wireless telecommunications market. The requested PhD student will gain experience in both the industrial and academic worlds and the skills needed to be part of Australia's high-tech workforce. Read moreRead less
Self-assembly and complexity: networks and patterns from materials to markets. Self-assembly leads the formation of patterns without external directing agents. It is responsible for the growth of complex multiscale structures found in biology and materials science and is a crucial concept for development of viable nanotechnologies. Complex systems, from biological ecosystems to financial markets and the Internet, are also characterized by spontaneous clustering and linkages that determine their ....Self-assembly and complexity: networks and patterns from materials to markets. Self-assembly leads the formation of patterns without external directing agents. It is responsible for the growth of complex multiscale structures found in biology and materials science and is a crucial concept for development of viable nanotechnologies. Complex systems, from biological ecosystems to financial markets and the Internet, are also characterized by spontaneous clustering and linkages that determine their collective behaviour. The project will investigate in detail the geometry, topology, materials science and statistical physics of networks, leading to design and characterization of robust self-assembled materials and complex systems.Read moreRead less
Towards a high density silicon phase change memory device. This project builds upon our exciting recent findings that amorphous silicon can be transformed to a conducting crystalline phase following small-scale indentation. Furthermore the process is reversible as re-indentation can induce a transformation back to insulating amorphous silicon. This process appears to occur in extremely small (nanoscale) volumes of silicon. We plan to explore the viability of exploiting this behaviour to develo ....Towards a high density silicon phase change memory device. This project builds upon our exciting recent findings that amorphous silicon can be transformed to a conducting crystalline phase following small-scale indentation. Furthermore the process is reversible as re-indentation can induce a transformation back to insulating amorphous silicon. This process appears to occur in extremely small (nanoscale) volumes of silicon. We plan to explore the viability of exploiting this behaviour to develop an entirely new information storage system: a high-density silicon phase change memory. This project aims to study small-scale transformation behaviour in silicon and to design demonstrator memory devices based on both micro-electromechanical systems and solid state technologies.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100096
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
A unique soft matter high-performance scanning probe microscopy (HP-SPM) facility. Soft matter research touches every aspect of our lives as it covers materials from the range of plastics found in cars, television sets and other mass-manufactured products, to new medical materials for tissue engineering and sensors. The proposed facility will enable Australia's leading scientists in this area to understand better how soft matter, including both biological and new advanced soft materials, behave ....A unique soft matter high-performance scanning probe microscopy (HP-SPM) facility. Soft matter research touches every aspect of our lives as it covers materials from the range of plastics found in cars, television sets and other mass-manufactured products, to new medical materials for tissue engineering and sensors. The proposed facility will enable Australia's leading scientists in this area to understand better how soft matter, including both biological and new advanced soft materials, behaves on the nano-scale level. This will put Australian researchers and engineers in a leading position for developing new treatments against cancer and other diseases, as well as harnessing the power of biology for application in areas such as waste treatment and energy production.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882576
Funder
Australian Research Council
Funding Amount
$588,000.00
Summary
Polymer Characterization Facility (PCF). Future development of macromolecular and biotechnologies have the potential to revolutionize everyday life. Current applications include plastics for engineering, diagnostic devices for biochemical analysis, polymer therapeutics for drug delivery and prosthesis with specific functions. The proposed facility will provide the analytical tools required to probe and develop advanced materials with application in medicine, agriculture, composites, cosmetics, ....Polymer Characterization Facility (PCF). Future development of macromolecular and biotechnologies have the potential to revolutionize everyday life. Current applications include plastics for engineering, diagnostic devices for biochemical analysis, polymer therapeutics for drug delivery and prosthesis with specific functions. The proposed facility will provide the analytical tools required to probe and develop advanced materials with application in medicine, agriculture, composites, cosmetics, communications and electronics.Read moreRead less
Self-assembled polyphiles: molecular nanopatterns. 21st century technology is certain to rely on advanced materials, utterly new in character, function and manufacturing process. Control of material structure, from the atomic and molecular scales and upward will be a central focus, to engineer specific features from electronic or photonic functionality, to chemical selectivity. The manufacturing principle of biological materials, made routinely in vivo with exquisite economy and control at all l ....Self-assembled polyphiles: molecular nanopatterns. 21st century technology is certain to rely on advanced materials, utterly new in character, function and manufacturing process. Control of material structure, from the atomic and molecular scales and upward will be a central focus, to engineer specific features from electronic or photonic functionality, to chemical selectivity. The manufacturing principle of biological materials, made routinely in vivo with exquisite economy and control at all length scales, will be adopted for materials design. The route to these materials is self-assembly. We will explore in detail theory and practical manufacture of self-assembled nanostructured materials, building molecular honeycombs combining composite material features at the nanoscale.Read moreRead less
Salt, Sugar and Sequence: The Effect of Molecular Forces on Polymer Conformation. We propose a combined experimental and theoretical investigation of single polymer chains, exploring how their shape or conformation, and stretching characteristics are affected by specific molecular interactions. Our tools in this study are both experimental and theoretical: optical tweezers, atomic force microscopy, as well as new theories in colloid science, and computer simulation. In particular, we will exa ....Salt, Sugar and Sequence: The Effect of Molecular Forces on Polymer Conformation. We propose a combined experimental and theoretical investigation of single polymer chains, exploring how their shape or conformation, and stretching characteristics are affected by specific molecular interactions. Our tools in this study are both experimental and theoretical: optical tweezers, atomic force microscopy, as well as new theories in colloid science, and computer simulation. In particular, we will examine the effect of different salts and sugars upon the properties of polymers such as DNA, and how monomer sequence can lead to dramatically different structures in solution which in turn will lead to novel materials.Read moreRead less
New Polymers for Cellulose-based Bioplastics. We will design new cellulose derivatives by combining carefully engineered synthetic polymers to cellulose. We will explore the fundamental science underpinning the manufacture of these bioplastics, and apply the concept to the design of two new materials, with (super)hydrophobic and antibacterial properties. These materials have the potential to replace synthetic plastics, which comprise one of the major outputs of the chemical industry worldwide. P ....New Polymers for Cellulose-based Bioplastics. We will design new cellulose derivatives by combining carefully engineered synthetic polymers to cellulose. We will explore the fundamental science underpinning the manufacture of these bioplastics, and apply the concept to the design of two new materials, with (super)hydrophobic and antibacterial properties. These materials have the potential to replace synthetic plastics, which comprise one of the major outputs of the chemical industry worldwide. Plastic is present everywhere in human life, but its manufacture and disposal have a strong negative impact on the environment; the new materials manufactured in this project are viable alternatives to plastics, and are sustainable from a production and disposal point of view.Read moreRead less
Chemical listening devices: Novel sensors targeting the clandestine manufacture and transport of illicit drugs and explosives. There can be no doubt that protecting Australia's borders from the dual threats of terrorism and illicit drugs is of paramount importance to continuation of our well-being and way of life. Our chemical sensors are simple hand-held or remote chemical listening sensors, which will have the ability to sense the presence of characteristic chemical vapours associated with exp ....Chemical listening devices: Novel sensors targeting the clandestine manufacture and transport of illicit drugs and explosives. There can be no doubt that protecting Australia's borders from the dual threats of terrorism and illicit drugs is of paramount importance to continuation of our well-being and way of life. Our chemical sensors are simple hand-held or remote chemical listening sensors, which will have the ability to sense the presence of characteristic chemical vapours associated with explosives and illicit drugs. The simplicity and low cost of the chemical listening allows for installation at key locations -e.g. transport hubs, shipping containers, airports etc as well as placement within clandestine drug laboratories.Read moreRead less
Development of Methods and Strategies for the Measurement, Interpretation and Analysis of Diffuse X-ray Scattering from Disordered Materials. This application seeks to exploit our established lead in the measurement of diffuse scattering from disordered materials and its analysis using large-scale computer simulations. Many industrially important materials such as ceramics, superconductors, catalysts, electro-optical materials and minerals owe their special properties to the disorder in their st ....Development of Methods and Strategies for the Measurement, Interpretation and Analysis of Diffuse X-ray Scattering from Disordered Materials. This application seeks to exploit our established lead in the measurement of diffuse scattering from disordered materials and its analysis using large-scale computer simulations. Many industrially important materials such as ceramics, superconductors, catalysts, electro-optical materials and minerals owe their special properties to the disorder in their structure. This disorder causes diffuse X-ray scattering which can be probed using synchrotron X-rays and powerful computers to reveal details about the material's nanoscale structure. The new methodology being developed will enhance our detailed understanding of the relationships between structure and properties in materials and help promote the design of new materials. Read moreRead less