Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100033
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Equipment for Advanced Surface Analysis. Equipment for advanced surface analysis:
This project aims to establish equipment for advanced surface analysis to provide Australian researchers with cutting-edge capabilities in surface science. Vital chemical and physical reactions often occur at surfaces. Understanding these reactions requires analysis of the composition and electronic structure of the surface and near-surface regions. Neutral impact collision ion scattering spectroscopy and inverse ....Equipment for Advanced Surface Analysis. Equipment for advanced surface analysis:
This project aims to establish equipment for advanced surface analysis to provide Australian researchers with cutting-edge capabilities in surface science. Vital chemical and physical reactions often occur at surfaces. Understanding these reactions requires analysis of the composition and electronic structure of the surface and near-surface regions. Neutral impact collision ion scattering spectroscopy and inverse photoemission spectroscopy measure concentration depth profiles and electronic structure. The depth resolution of the profiles is in the order of the distance between two neighbouring atoms in a solid or liquid and is the best currently achievable. The equipment providing these capabilities is expected to support research with applications in photovoltaics, catalysis, colloid surfaces and interfaces, coatings and nanocomposites.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
Electrical spin resonance detection techniques for nanotechnology applications. Spin resonance, the science which underpins magnetic resonance imaging, is an extemely useful tool which is currently incompatible with nanotechnology. This project will develop methods to integrate spin resonance techniques and nanotechnology, which will significantly impact both fundamental research and technological advances.
Discovery Early Career Researcher Award - Grant ID: DE180100314
Funder
Australian Research Council
Funding Amount
$353,773.00
Summary
Engineering magnetism at the atomic scale in topological insulators. This project aims to explore strategies to optimise the magnetisation and Curie temperature by incorporating dopants via ion implantation, and exploiting proximity effects in heterostructures with magnetic thin films. The recently discovered magnetism in topological insulators opens up a new class of materials with potential applications in energy-efficient electronics, data storage and information processing. The central chall ....Engineering magnetism at the atomic scale in topological insulators. This project aims to explore strategies to optimise the magnetisation and Curie temperature by incorporating dopants via ion implantation, and exploiting proximity effects in heterostructures with magnetic thin films. The recently discovered magnetism in topological insulators opens up a new class of materials with potential applications in energy-efficient electronics, data storage and information processing. The central challenges are to control the underlying magnetic structure and stabilise magnetic order at desirable temperatures. The project expects to discover new composite materials and advance our knowledge for designing magnetic components in the next generation of electronics with ultra-low power dissipation.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100235
Funder
Australian Research Council
Funding Amount
$180,000.00
Summary
Interfacial mapping facility. New electronic materials and devices impact on everyday life in areas such as photovoltaics, biotechnology and healthcare. This facility will provide researchers with the unique capability of mapping both the structure and electronic properties of materials on the nanoscale. It will be an essential tool for developing new electronics based on nanotechnology.
Nonlinear Optical Metrology of Electronic Interfaces for Silicon Devices. This project aims to develop a prototype electric field induced second harmonic generation metrology setup for studying thin film dielectric interfaces on silicon in partnership with Femtometrix. The quality of these silicon-dielectric interfaces, which are affected by trapped charges and defects, are critical for microelectronic and optoelectronic device manufacturing. Through several proposed methodologies to separate th ....Nonlinear Optical Metrology of Electronic Interfaces for Silicon Devices. This project aims to develop a prototype electric field induced second harmonic generation metrology setup for studying thin film dielectric interfaces on silicon in partnership with Femtometrix. The quality of these silicon-dielectric interfaces, which are affected by trapped charges and defects, are critical for microelectronic and optoelectronic device manufacturing. Through several proposed methodologies to separate the effect of interface and bulk signals, it is expected that the sensitivity of the prototype setup will exceed the previous record of 1 kV/cm. This metrology technique will be further expanded for applicability to silicon photovoltaics, specifically passivating contacts which cannot be studied via conventional techniques.Read moreRead less
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.
The best of both worlds: electrically detected optical spectroscopy at the single atom limit. One atom, one photon, one electron, in a silicon crystal. We will demonstrate a novel technique to detect the absorption of light by a single atom, in the most significant environment for nanoelectronics and photovoltaics. Our technique will help unravel how light is turned into electricity at the most microscopic and fundamental level.
Hot Topic: Quantum Design of Phononic Heat Filters. Heat management is critical to many technologies for sustainable energy, electronics, protective equipment and energy-efficient buildings. The phonon is the quantum particle representing a travelling vibration and is responsible for the transmission of heat in solids. This project will study the new mechanisms for phonon transport in solids modified with embedded nanoparticles, which operate as phononic filters. Neutron spectroscopy provides a ....Hot Topic: Quantum Design of Phononic Heat Filters. Heat management is critical to many technologies for sustainable energy, electronics, protective equipment and energy-efficient buildings. The phonon is the quantum particle representing a travelling vibration and is responsible for the transmission of heat in solids. This project will study the new mechanisms for phonon transport in solids modified with embedded nanoparticles, which operate as phononic filters. Neutron spectroscopy provides a tool to measure the phonon density of states which is critical for developing a mathematical model of thermal boundary resistance. This is expected to identify mechanisms for ultra-low thermal conductivity leading to potential applications in thermoelectric generators and heat-resistant materials.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL130100171
Funder
Australian Research Council
Funding Amount
$2,863,442.00
Summary
Computers of the future: atomic-scale logic. Building upon internationally recognised leadership in the development of atomic-scale electronic devices, this project aims to achieve the ultimate in computer miniaturisation: to develop components for the world's first integrated circuit, where all elements are constructed on the atomic scale.