Electronic functionality in nanoscale materials: from discovery to design. This project will develop innovative multifunctional carbon/boron-nitride nanomaterials by devising new strategies to manipulate their electronic functionality. Outcomes will include technological breakthroughs leading to smart materials for energy storage, greenhouse gas emission reduction and nanoelectronics.
Ion-beam synthesis of functional oxides for next generation memory devices. This project seeks to explore a low-temperature approach to stoichiometry control using direct oxide synthesis and defect-engineering based on ion-implantation, a routine semiconductor fabrication process. This has the potential to improve device manufacturability and functionality. In thin film form, transition metal oxides can be subjected to intense electric fields and exhibit characteristic resistance changes suitabl ....Ion-beam synthesis of functional oxides for next generation memory devices. This project seeks to explore a low-temperature approach to stoichiometry control using direct oxide synthesis and defect-engineering based on ion-implantation, a routine semiconductor fabrication process. This has the potential to improve device manufacturability and functionality. In thin film form, transition metal oxides can be subjected to intense electric fields and exhibit characteristic resistance changes suitable for non-volatile memory applications. However, their electrical response depends critically on stoichiometry and this must be precisely engineered for optimal device performance. This project aims to develop next-generation memory devices as a replacement for current flash memory. The proposed technology uses resistance changes in functional-oxides to store information, and offers the potential for smaller and faster memory.Read moreRead less
Controlling the forming and switching characteristics of non-volatile resistive memory devices using ion-implantation. This project will develop new techniques for improving the reliability and endurance of a new class of non-volatile memory devices for use in portable electronics and embedded electronic systems. Such developments are essential for the development of next-generation devices.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100109
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
A multiscale electrochemical, magnetoelectric and electromechanical characterisation facility for advanced materials and devices. This infrastructure for advanced materials characterisation will boost Australia's capabilities in creating functional materials and nanostructured interfaces. It will yield new materials and functional interfaces with the best performance for applications in nanotechnology, communications, the environment and security.
Hole quantum dots - a new spin on quantum information technology. Most electronic devices are powered by conventional transistors that use a 50 year old technology which is nearing the end of its lifetime. Spin-based electronics uses the electron's spin instead of its charge to store, process and transfer information. Although half of all transistors on a chip use holes, almost all research has focussed on electrons. Holes have completely different spin properties than electrons and are predicte ....Hole quantum dots - a new spin on quantum information technology. Most electronic devices are powered by conventional transistors that use a 50 year old technology which is nearing the end of its lifetime. Spin-based electronics uses the electron's spin instead of its charge to store, process and transfer information. Although half of all transistors on a chip use holes, almost all research has focussed on electrons. Holes have completely different spin properties than electrons and are predicted to have significant advantages for spin based quantum information processing. This project aims to develop single hole quantum dots, test theoretical predictions of the superiority of holes over electrons and develop new techniques for all-electrical spin manipulation.Read moreRead less
A new spin on semiconductor quantum information technology. Future advances in computer technology will exploit quantum physics to deliver increased computational power, either through new materials or quantum information approaches. However although half of the 100 billion transistors in your iphone use holes to operate, most semiconductor quantum research has focussed on electrons. Holes have completely different quantum spin properties than electrons; recent advances show holes have highly de ....A new spin on semiconductor quantum information technology. Future advances in computer technology will exploit quantum physics to deliver increased computational power, either through new materials or quantum information approaches. However although half of the 100 billion transistors in your iphone use holes to operate, most semiconductor quantum research has focussed on electrons. Holes have completely different quantum spin properties than electrons; recent advances show holes have highly desirable properties for spin based quantum information. This project will work with leading European laboratories to develop quantum computer components based on hole spin in quantum dots in industrially relevant semiconductors, and demonstrate a pathway towards a scalable quantum computer architecture.
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Single hole quantum dots for spin-based electronics. This project will support a basic research initiative in an area with enormous potential for the trillion dollar semiconductor industry. Working with the international University partners, we will develop new electronic devices that use holes, rather than electrons, to operate.
Organic Field Effect Transistors for Biosensor Applications. The development of future Australian industries based on polymer electronics is tangible. The prohibitive establishment costs mean that there is effectively no Australian conventional semiconductor manufacturing industry. However, polymer electronic devices are simple to manufacture with low fabrication costs. As such, the commercial barriers to the development of an Australian soft electronics industry are much lower. Internationally, ....Organic Field Effect Transistors for Biosensor Applications. The development of future Australian industries based on polymer electronics is tangible. The prohibitive establishment costs mean that there is effectively no Australian conventional semiconductor manufacturing industry. However, polymer electronic devices are simple to manufacture with low fabrication costs. As such, the commercial barriers to the development of an Australian soft electronics industry are much lower. Internationally, soft electronics is developing apace and securing a soft electronics industry in Australia requires the urgent development of an Australian skill base in fabricating soft electronic devices. This project offers the opportunity of establishing a significant capability in soft electronic device fabrication.Read moreRead less
Bioelectronic logic. This project aims to understand ion-electron interactions relevant to bioelectronics, and create transducing interfaces. Bioelectronics is a frontier field which aims to connect biological systems with modern electronics and so create biomedical devices. Transducing ion and electron signals using a biocompatible functional interface is difficult since ion and electron physics are different. By combining individual transducers, this project intends to demonstrate ground-break ....Bioelectronic logic. This project aims to understand ion-electron interactions relevant to bioelectronics, and create transducing interfaces. Bioelectronics is a frontier field which aims to connect biological systems with modern electronics and so create biomedical devices. Transducing ion and electron signals using a biocompatible functional interface is difficult since ion and electron physics are different. By combining individual transducers, this project intends to demonstrate ground-breaking bioelectronic logic capable of interface-level processing. The stretch goal is to test this new logic with a biological neuronal model. The project could deliver new science and interfacing elements to integrate tissue and circuitry, and demonstrate these in a real biological model.Read moreRead less
Elastically controlled magnetoelectric transduction in thin film multilayers. Ferroelectric and ferromagnetic materials have attracted significant attention and exhibited potential in many applications such as storage memories, solid-state light sources and a range of smart chemical and biological sensors. This proposal seeks to investigate the behaviour of these materials in layered form, where an imposed mechanical traction induces novel combinations of ferroelectric and magnetic properties. T ....Elastically controlled magnetoelectric transduction in thin film multilayers. Ferroelectric and ferromagnetic materials have attracted significant attention and exhibited potential in many applications such as storage memories, solid-state light sources and a range of smart chemical and biological sensors. This proposal seeks to investigate the behaviour of these materials in layered form, where an imposed mechanical traction induces novel combinations of ferroelectric and magnetic properties. The fundamental understanding of the behaviour of these materials will help us develop new material systems with exciting possibilities in the design of advanced devices and sensors.Read moreRead less