Neural Mechanisms Of Language Facilitation In Aphasia Due To Transcranial Direct Current Stimulation.
Funder
National Health and Medical Research Council
Funding Amount
$523,192.00
Summary
This project will assess the underlying neural mechanisms by which neurostimulation improves impaired language functions after stroke (aphasia). This will be accomplished by using a novel combination of functional magnetic resonance imaging and simultaneous transcranial direct current stimulation (tDCS) administered to different brain regions. These studies will provide crucial information necessary to optimise future clinical trials that combine tDCS with language therapy.
Interlayer magnetoresistance of strongly correlated electron materials. The continued rapid expansion of information and entertainment technology requires new materials and devices for information storage. State of the art computer and iPod memories utilise advanced materials composed of layers of atoms, recognised by the 2007 Nobel Prize in Physics. These materials have metallic properties quite unlike those of simple metals such as copper and brass. This research will lead to a greater underst ....Interlayer magnetoresistance of strongly correlated electron materials. The continued rapid expansion of information and entertainment technology requires new materials and devices for information storage. State of the art computer and iPod memories utilise advanced materials composed of layers of atoms, recognised by the 2007 Nobel Prize in Physics. These materials have metallic properties quite unlike those of simple metals such as copper and brass. This research will lead to a greater understanding of and ability to design the next generation of materials. Australia's capacity for research and development in this scientifically challenging and technologically important field will be enhanced by this project. Read moreRead less
The theory of interferometers in nano-scale electronics. Soon the electronic circuits in computer chips will be so small that new effects due to quantum phyiscs will become important.
The proposed research will provide a better understanding of a range of nano-scale electronic devices including electron interferometers based on quantum points contacts and quantum dots.
Sepcifically, a new understanding of quantum coherent phenomena
in nano-scale interferometers will offers a potential ap ....The theory of interferometers in nano-scale electronics. Soon the electronic circuits in computer chips will be so small that new effects due to quantum phyiscs will become important.
The proposed research will provide a better understanding of a range of nano-scale electronic devices including electron interferometers based on quantum points contacts and quantum dots.
Sepcifically, a new understanding of quantum coherent phenomena
in nano-scale interferometers will offers a potential application
to other quantum technologies important to the future
of computing.
Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882224
Funder
Australian Research Council
Funding Amount
$440,000.00
Summary
Vector Magnetic Field Facility for Nanoscale Spintronic Materials and Device Research. Electronic devices underpin a trillion dollar industry worldwide and are an essential part of modern life. Spintronics (spin-electronics) is an emergent technology that combines the electrical and magnetic properties of electrons to represent and process information. Spintronic chips are expected to be fast, versatile, capable of simultaneous data storage and processing, while at the same time consuming less ....Vector Magnetic Field Facility for Nanoscale Spintronic Materials and Device Research. Electronic devices underpin a trillion dollar industry worldwide and are an essential part of modern life. Spintronics (spin-electronics) is an emergent technology that combines the electrical and magnetic properties of electrons to represent and process information. Spintronic chips are expected to be fast, versatile, capable of simultaneous data storage and processing, while at the same time consuming less energy. Industry analysts suggest the spintronic market will exceed $10 billion. This facility will provide the critical infrastructure needed to study the electronic and magnetic properties of nanostructured materials, providing the underpinning knowledge to develop the next generation of spintronic devices.Read moreRead less
Decoherence and Quantum Simulations of Spin-Environment systems. The effort to develop quantum technologies relies on our ability to understand and manipulate quantum mechanical objects with great precision. In order to do this, we need to study how such systems interact with their surroundings. Solid-state quantum systems connected to an environment show a rich range of phenomena, such as quantum phase transitions, which are interesting in their own right. This work will better enable experi ....Decoherence and Quantum Simulations of Spin-Environment systems. The effort to develop quantum technologies relies on our ability to understand and manipulate quantum mechanical objects with great precision. In order to do this, we need to study how such systems interact with their surroundings. Solid-state quantum systems connected to an environment show a rich range of phenomena, such as quantum phase transitions, which are interesting in their own right. This work will better enable experimentalists to develop the techniques required for the future of quantum technology.Read moreRead less
Nonlinear quantum science with superconducting circuit quantum-electrodynamics. Circuit quantum electrodynamics has rapidly emerged in recent years as a new field of experimental quantum science, with applications to precision measurement, nanomechanical transducers and quantum information processing. We will design and demonstrate new experimental devices, grounded in a long-standing expertise in quantum optics, and enabled by a new low temperature laboratory under development at The Universit ....Nonlinear quantum science with superconducting circuit quantum-electrodynamics. Circuit quantum electrodynamics has rapidly emerged in recent years as a new field of experimental quantum science, with applications to precision measurement, nanomechanical transducers and quantum information processing. We will design and demonstrate new experimental devices, grounded in a long-standing expertise in quantum optics, and enabled by a new low temperature laboratory under development at The University of Queensland. This project will deliver a new technological capability for Australia.Read moreRead less
Modelling Superconducting Quantum Devices. The capability to incorporate quantum mechanical systems into electronic circuits leads to devices with fundamentally new properties. These devices are very sensitive to their environment, so can be used as sensitive sensors. In the extreme, with many such devices connected together, it would lead to a full scale quantum computer, which has the capacity to perform tasks that are unfeasible on an ordinary computer. This proposal aims to characterise ....Modelling Superconducting Quantum Devices. The capability to incorporate quantum mechanical systems into electronic circuits leads to devices with fundamentally new properties. These devices are very sensitive to their environment, so can be used as sensitive sensors. In the extreme, with many such devices connected together, it would lead to a full scale quantum computer, which has the capacity to perform tasks that are unfeasible on an ordinary computer. This proposal aims to characterise quantum electronics from a theoretical perspective, complimentary to experimental efforts that will soon begin at the University of Queensland.Read moreRead less
Modelling quantum dynamics of electronic excited states in complex molecular materials. Understanding new materials that are the basis of new sources of renewable energy sources represents a major scientific challenge. Many of these materials are composed of large organic molecules containing hundreds of atoms. Their properties and the concepts needed to understand these materials are distinctly different from semiconductors such as silicon. This research will enhance our ability to design bett ....Modelling quantum dynamics of electronic excited states in complex molecular materials. Understanding new materials that are the basis of new sources of renewable energy sources represents a major scientific challenge. Many of these materials are composed of large organic molecules containing hundreds of atoms. Their properties and the concepts needed to understand these materials are distinctly different from semiconductors such as silicon. This research will enhance our ability to design better materials and optimize the performance of organic solar cells and LEDs. Australia's capacity for research and development in this scientifically challenging and technologically important field will be enhanced by this project. Read moreRead less