Innovative Stable Free Radical-Substituted Conjugated Electronic Polymers. The project aims to develop an innovative class of stable free radicals side-chain substituted conjugated donor-acceptor electronic polymers with unique polaronic and radical charge transport capabilities. The targeted optoelectronic material class is unique and has not been explored in depth before. The combination of unpaired electrons and delocalized backbone -electrons delivers exciting modes of charge transfer that ....Innovative Stable Free Radical-Substituted Conjugated Electronic Polymers. The project aims to develop an innovative class of stable free radicals side-chain substituted conjugated donor-acceptor electronic polymers with unique polaronic and radical charge transport capabilities. The targeted optoelectronic material class is unique and has not been explored in depth before. The combination of unpaired electrons and delocalized backbone -electrons delivers exciting modes of charge transfer that provide these novel materials with clear potential as electroactive materials with applications in various nanoelectronics devices. Developing a fundamental understanding of charge transport properties and potential device applications will open up a new field of research in advanced optoelectronic technology. Read moreRead less
2D Multiferroics: From Materials Design to Device Conceptualization. This project aims to design new transistors with high efficiency and low energy costing for the storage applications based on two-dimensional multifunctional heterostructures. Extensive computational simulations and joint experiments will be employed to develop fundamental knowledge essential to understanding the phenomena of magnetoelectric coupling, which is used to guide rational device design and implementation. The designe ....2D Multiferroics: From Materials Design to Device Conceptualization. This project aims to design new transistors with high efficiency and low energy costing for the storage applications based on two-dimensional multifunctional heterostructures. Extensive computational simulations and joint experiments will be employed to develop fundamental knowledge essential to understanding the phenomena of magnetoelectric coupling, which is used to guide rational device design and implementation. The designed magnetoelectric heterostructures and the multiferroic devices are expected to provide strong foundations for technological innovations resulting in devices with superior functionality and efficiency. The outcome of the project will significantly benefit high-tech electronics.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100190
Funder
Australian Research Council
Funding Amount
$205,000.00
Summary
High through-put facility for measurement of quantum materials and devices. This projects aims to accelerate the development of quantum technologies by expanding our capacity to rapidly evaluate the low temperature electrical and optical properties of novel materials and devices. The project expects to generate new knowledge in quantum coherent phases of diamond, high mobility two-dimensional spintronics, hybrid semiconductor-superconductor devices, novel phases of silicon and germanium, and sin ....High through-put facility for measurement of quantum materials and devices. This projects aims to accelerate the development of quantum technologies by expanding our capacity to rapidly evaluate the low temperature electrical and optical properties of novel materials and devices. The project expects to generate new knowledge in quantum coherent phases of diamond, high mobility two-dimensional spintronics, hybrid semiconductor-superconductor devices, novel phases of silicon and germanium, and single photon sources based on silicon-carbide. Expected outcomes of the project include the establishment of high performing, efficient, new facilities for low temperature quantum measurement, the strengthening of collaborative links between participating researchers and the expansion of opportunities for research students.Read moreRead less
Enabling diamond nanoelectronics with metal oxide induced surface doping. This project aims to use diamond for radio frequency power electronics. This builds on the investigator’s success in controlling diamond surface conductivity using transition metal oxides. Diamond is highly desirable for building high-power, high-frequency electronic devices, particularly for use in electrical power control/conversion and telecommunication. The lack of effective and stable doping methods has impeded the re ....Enabling diamond nanoelectronics with metal oxide induced surface doping. This project aims to use diamond for radio frequency power electronics. This builds on the investigator’s success in controlling diamond surface conductivity using transition metal oxides. Diamond is highly desirable for building high-power, high-frequency electronic devices, particularly for use in electrical power control/conversion and telecommunication. The lack of effective and stable doping methods has impeded the realisation of this prospect. This project expects the high performance and technically viable device technologies will enable diamond electronic devices for applications in telecommunications, radars and the next-generation electricity grid.Read moreRead less
Stretchable Organic Transistors for Wearable Electronics and Robotics. The project aims to address the challenges of fabricating stretchable organic transistors for applications in wearable electronics and robotics through the development of new semiconducting polymers with stretchability and integrating them into novel, stretchable organic transistor configurations. The project will take a molecular engineering approach to the complex needs of this challenge by combining appropriate chemical f ....Stretchable Organic Transistors for Wearable Electronics and Robotics. The project aims to address the challenges of fabricating stretchable organic transistors for applications in wearable electronics and robotics through the development of new semiconducting polymers with stretchability and integrating them into novel, stretchable organic transistor configurations. The project will take a molecular engineering approach to the complex needs of this challenge by combining appropriate chemical functionality which provides high charge carrier mobility with judiciously placed flexible spacers and side chains to provide mechanical dexterity. These novel polymers will be integrated into transistor structures and their fabricated arrays deposited on stretchable substrates will be used for a real world applications.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100146
Funder
Australian Research Council
Funding Amount
$800,000.00
Summary
Ultra high vacuum scanning probe microscope facility. Ultra high-vacuum scanning tunneling microscopy underpins advances in the understanding of novel materials for electronics, engineering and medical applications, including thin-films, nanostructures, advanced semiconductors, nanostructured (organic or inorganic) conductors, and nanoscale interfaces (heteronanostructures). It is a core technique underpinning the new Superscience agenda in Future Technologies. A number of present and future re ....Ultra high vacuum scanning probe microscope facility. Ultra high-vacuum scanning tunneling microscopy underpins advances in the understanding of novel materials for electronics, engineering and medical applications, including thin-films, nanostructures, advanced semiconductors, nanostructured (organic or inorganic) conductors, and nanoscale interfaces (heteronanostructures). It is a core technique underpinning the new Superscience agenda in Future Technologies. A number of present and future research fields will benefit from the presence of this instrument, which will enhance Australia's competitiveness in nanotechnology research and development. Training of PhD and graduate students in this area is essential to exploit the potentiality of nanotechnology for the future benefit of Australia.Read moreRead less
Novel circuits and design strategies for sub-65 nanometre complementary metal oxide semiconductor technologies. This project will develop novel, state-of-the-art circuits and design strategies that overcome the challenges of current and future Integrated Circuit (IC) fabrication technologies. The extremely small sizes of transistors in these technologies offer advantages in speed, but at the price of a number of drawbacks, which the project will aim to overcome in this work. This research will m ....Novel circuits and design strategies for sub-65 nanometre complementary metal oxide semiconductor technologies. This project will develop novel, state-of-the-art circuits and design strategies that overcome the challenges of current and future Integrated Circuit (IC) fabrication technologies. The extremely small sizes of transistors in these technologies offer advantages in speed, but at the price of a number of drawbacks, which the project will aim to overcome in this work. This research will make a significant contribution to the field of IC design as well as providing training for students to fill the present and future needs of Australia's IC design companies. Some of the most advanced cochlear implants, mobile phone ICs, and Wireless Internet ICs have been designed in Australia, and companies in Australia desperately need graduates skilled in designing in the latest technologies.Read moreRead less
Synthesis of enriched silicon for long-lived donor quantum states. We have discovered a method to make silicon highly enriched in the desirable spin-zero isotope using readily available ion implantation tools. This “semiconductor vacuum” is essential for building future quantum computer devices using the quantum spin of millions of implanted atoms with revolutionary capabilities. We have demonstrated long-lived implanted donor atom quantum states in prototype material, made possible by the deple ....Synthesis of enriched silicon for long-lived donor quantum states. We have discovered a method to make silicon highly enriched in the desirable spin-zero isotope using readily available ion implantation tools. This “semiconductor vacuum” is essential for building future quantum computer devices using the quantum spin of millions of implanted atoms with revolutionary capabilities. We have demonstrated long-lived implanted donor atom quantum states in prototype material, made possible by the depletion of background spins in natural silicon and now aim to push the enrichment to greater extremes. We will integrate the extreme material into functional devices that use electrically detected electron spin resonance to probe exceptionally durable quantum states and open a near-term pathway to large-scale devices.Read moreRead less
Surface doping of diamond: A new platform for 2D carbon-based spintronics. This project aims to develop the hydrogen-terminated surface of diamond as a new semiconducting platform for carbon-based spintronics. It will build upon recent experimental advances that have shown diamond to possess a two-dimensional (2D) hole-based system with strong spin-orbit coupling. As a semiconductor with unique spin properties, surface conducting diamond offers considerable advantages over other 2D materials su ....Surface doping of diamond: A new platform for 2D carbon-based spintronics. This project aims to develop the hydrogen-terminated surface of diamond as a new semiconducting platform for carbon-based spintronics. It will build upon recent experimental advances that have shown diamond to possess a two-dimensional (2D) hole-based system with strong spin-orbit coupling. As a semiconductor with unique spin properties, surface conducting diamond offers considerable advantages over other 2D materials such as graphene and topological insulators. These unique properties will be exploited to realise novel semiconductor device architectures for the manipulation of spin using electric fields, and for the study of new spin transport phenomena and quasiparticle excitations at semiconductor-superconductor interfaces.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100124
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Rapid prototyping 3-D nano-pattern large area writer . Rapid prototyping 3-D nano-pattern large area writer:
The project aims to establish a nanoscale three-dimensional patterning rapid prototyping capability to enable advanced nanofabrication research and development. The extension of patterning nanostructured materials in three dimensions with nanometre resolution, developed for semiconductor processing, to nano-electronics, nanophotonics, nanosensors, nanobiotechnology and fundamental studi ....Rapid prototyping 3-D nano-pattern large area writer . Rapid prototyping 3-D nano-pattern large area writer:
The project aims to establish a nanoscale three-dimensional patterning rapid prototyping capability to enable advanced nanofabrication research and development. The extension of patterning nanostructured materials in three dimensions with nanometre resolution, developed for semiconductor processing, to nano-electronics, nanophotonics, nanosensors, nanobiotechnology and fundamental studies of nanoscale phenomena in science and engineering has opened new opportunities in these areas. As these areas accelerate, there is a need to develop nanoscale patterns and structures via rapid prototyping pathways and with methods accessible to an ever-diverse researcher base without a background in nanofabrication. By establishing the first NanoFrazor in Australia, this project aims to provide new technology for the fabrication of high-resolution nanoscale structures and patterns.
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