Magnetic and electric field tuneable magnetic heterostructures. Australian science and technology will be a leading participant in the creation of a new, useful magneto-electric composite material whose properties arise from careful atomic level design. This goal has been long sought after, and only recently come within reach. Recent proof-of-concept demonstrations have inspired an explosion of activity on a global scale together with intensive searches for additional examples of useful materia ....Magnetic and electric field tuneable magnetic heterostructures. Australian science and technology will be a leading participant in the creation of a new, useful magneto-electric composite material whose properties arise from careful atomic level design. This goal has been long sought after, and only recently come within reach. Recent proof-of-concept demonstrations have inspired an explosion of activity on a global scale together with intensive searches for additional examples of useful material combinations. In this project, young Australian scientists and research students will have opportunities to receive training and become involved in a National Priority Frontier Technology rich in possibilities for generation of intellectual property.Read moreRead less
Memory effects in magnetic metals: origin, utility and control in magnetoelectronics using layered nanopatterns. The work is in the important area of magneto-electronics, a field recognised by the 2007 Nobel Prize awarded in Physics. Training opportunities for Honours and postgraduate students will be provided at the forefront of this high profile area, thereby expanding Australian knowledge base and capability. New opportunities for interaction between several groups in Australia will be create ....Memory effects in magnetic metals: origin, utility and control in magnetoelectronics using layered nanopatterns. The work is in the important area of magneto-electronics, a field recognised by the 2007 Nobel Prize awarded in Physics. Training opportunities for Honours and postgraduate students will be provided at the forefront of this high profile area, thereby expanding Australian knowledge base and capability. New opportunities for interaction between several groups in Australia will be created. The projects will involve PhD students shared between Australian institutions and collaborating groups overseas, thereby cementing collaborations while simultaneously providing unique training environments. The project will use and support activities associated with the Australian major facilities. Read moreRead less
Comparative Study of MnAs and Co-Based Magnetoelastic Functional Materials. Magnetoelastic materials are an emerging new class of functional materials with great potential in a wide range of innovative applications including smart structures, sensors and actuators, microelectronics, micro-electromechanical systems, and medical engineering. The study of magnetoelastic materials is still in its infancy and a great effort is required to develop them into practical materials for engineering applicat ....Comparative Study of MnAs and Co-Based Magnetoelastic Functional Materials. Magnetoelastic materials are an emerging new class of functional materials with great potential in a wide range of innovative applications including smart structures, sensors and actuators, microelectronics, micro-electromechanical systems, and medical engineering. The study of magnetoelastic materials is still in its infancy and a great effort is required to develop them into practical materials for engineering application. This study aims to investigate two promising candidate materials: CoNi and MnAs. Expected outcomes include the characterisation of their functional properties and understanding of the mechanisms of magnetoelasticity in these materials. Such understanding is expected to contribute to the development of practical magnetoelastic materials and their applications.
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Materials World Network for the Study of Macromolecular Ferrofluids. This work will develop an understanding that will allow us to optimise the properties of ferrofluids (magnetic liquids) to suit particular applications. Although the primary application that will be investigated is the treatment of retinal detachment, the results will be applicable to a wide range of applications including ferrofluid-based actuators, electromagnetic micropumps and fluid based valves and sealing systems. During ....Materials World Network for the Study of Macromolecular Ferrofluids. This work will develop an understanding that will allow us to optimise the properties of ferrofluids (magnetic liquids) to suit particular applications. Although the primary application that will be investigated is the treatment of retinal detachment, the results will be applicable to a wide range of applications including ferrofluid-based actuators, electromagnetic micropumps and fluid based valves and sealing systems. During the course of this work, young Australian scientists will be trained in a cross-disciplinary environment in a variety of aspects of both nano- and bio- technology that are a key part of the National Research Priority: Frontier Technologies for Building and Transforming Australian Industries.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100200
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
Advanced facility for magneto-transport characterisation of semiconductor nanostructures. This facility combines a 16 Tesla superconducting magnet with temperature variability from 1.5 degrees above absolute zero to 500 degrees with advanced mobility spectrum analysis algorithms. It will enable improved separation of previously indistinguishable multiple carrier effects in advanced semiconductor systems. This improved separation will allow an improved understanding of multiple carrier effects wh ....Advanced facility for magneto-transport characterisation of semiconductor nanostructures. This facility combines a 16 Tesla superconducting magnet with temperature variability from 1.5 degrees above absolute zero to 500 degrees with advanced mobility spectrum analysis algorithms. It will enable improved separation of previously indistinguishable multiple carrier effects in advanced semiconductor systems. This improved separation will allow an improved understanding of multiple carrier effects which will be essential before the development of frontier semiconductor technologies becomes possible.Read moreRead less