Complex Interfaces and Solid-State Precipitation in Advanced Materials. Solid-state precipitates are key features of the microstructures of many natural and artificial materials and govern their properties. Yet understanding, let alone designing, the microstructures of materials remains a formidable challenge. The recent discovery of a new class of embedded interfaces in aluminium alloys offers the prospect of determining the atomic-scale mechanisms of precipitation. This project aims to apply t ....Complex Interfaces and Solid-State Precipitation in Advanced Materials. Solid-state precipitates are key features of the microstructures of many natural and artificial materials and govern their properties. Yet understanding, let alone designing, the microstructures of materials remains a formidable challenge. The recent discovery of a new class of embedded interfaces in aluminium alloys offers the prospect of determining the atomic-scale mechanisms of precipitation. This project aims to apply the latest microscopy and computational techniques synergistically to characterise such interfaces and develop atomic-scale mechanisms of nucleation and growth in model alloy systems. It is expected that this work will constitute a major step towards practical control of solid-state precipitation in technologically important materials.Read moreRead less
From One Structure to Another for Improved Materials Design. This project aims to characterise a new way of generating strengthening precipitate structures for lightweight aluminium alloys. Precipitation in the solid state is key to the performance of many materials, but is especially important for light alloys used in structural applications. This project expects to deliver greater fundamental understanding of precipitation mechanisms and generate experimental and computational methods for thre ....From One Structure to Another for Improved Materials Design. This project aims to characterise a new way of generating strengthening precipitate structures for lightweight aluminium alloys. Precipitation in the solid state is key to the performance of many materials, but is especially important for light alloys used in structural applications. This project expects to deliver greater fundamental understanding of precipitation mechanisms and generate experimental and computational methods for three-dimensional characterisation and simulations at the atomic-scale of embedded nanostructures. This should provide significant benefits for the improved design of light alloys, such as for the automotive and aerospace sectors, but also for high-tech materials whose function depends on precipitates. Read moreRead less
Design and Fabrication of 2D Hybrid Materials. There are >300 2D materials like graphene with potentially exotic and useful electrooptic and superconductor properties that will drive novel industrial applications. This project aims to use advanced computational and experimental techniques to discover and fabricate new 2D hybrid materials built from different layers of 2D materials. This approach is essential as the number of possible hybrids is huge (millions) and current processes to identify a ....Design and Fabrication of 2D Hybrid Materials. There are >300 2D materials like graphene with potentially exotic and useful electrooptic and superconductor properties that will drive novel industrial applications. This project aims to use advanced computational and experimental techniques to discover and fabricate new 2D hybrid materials built from different layers of 2D materials. This approach is essential as the number of possible hybrids is huge (millions) and current processes to identify and build 2D hybrids are technically challenging and slow. Expected outcomes include defining a new paradigm for efficient identification and synthesis of 2D hybrids with exotic, bespoke properties. The generation of a large database of materials for researchers/industry would be of wide benefit.Read moreRead less
A theoretical hierachy to investigate the electronic behaviour of graphene nanostructures under realistic conditions. One of the most exciting new nano-materials is graphene which promises to be the basis of a new industry producing nano-electronics and nano-devices such as chemical sensors. This project aims to provide sound scientific knowledge on the effects of environmental conditions on the properties of graphene which are vital for its industrial use.
Discovery Early Career Researcher Award - Grant ID: DE160100987
Funder
Australian Research Council
Funding Amount
$306,186.00
Summary
Designing next generation smart materials for capturing toxic gases. The project aims to use rapid computational and experimental screening tools to speed the design and development of robust metal organic frameworks for detecting and capturing toxic gases. Detecting and capturing toxic gases is vital for numerous industrial processes. Metal organic frameworks are porous materials that hold the world record for specific surface area and storage of gases. Their development and application in prac ....Designing next generation smart materials for capturing toxic gases. The project aims to use rapid computational and experimental screening tools to speed the design and development of robust metal organic frameworks for detecting and capturing toxic gases. Detecting and capturing toxic gases is vital for numerous industrial processes. Metal organic frameworks are porous materials that hold the world record for specific surface area and storage of gases. Their development and application in practical conditions require stability in the operating environment. It is expected that this project will lead to the development of efficient and effective porous materials that detect and capture toxic gases, thus improving Australian industry’s ability to monitor and eliminate emissions, improving air quality and public health.Read moreRead less
Understanding and eliminating dissipation in superconducting devices: the origin of two-level defects. Superconducting quantum circuits constitute the next generation of nano-electronics. They find application in medicine, biology and geophysics; from mapping mineral deposits to imaging heart function, and are a promising candidate for quantum information processing and high speed electronics. A major loss mechanism within a Josephson junction (which forms the basis of a quantum circuit) is caus ....Understanding and eliminating dissipation in superconducting devices: the origin of two-level defects. Superconducting quantum circuits constitute the next generation of nano-electronics. They find application in medicine, biology and geophysics; from mapping mineral deposits to imaging heart function, and are a promising candidate for quantum information processing and high speed electronics. A major loss mechanism within a Josephson junction (which forms the basis of a quantum circuit) is caused by intrinsic two-level defects. What is not known is the true microscopic nature of these defects, although there are many theories. This project aims to unravel this mystery using detailed theoretical and computation analysis based on precision experimental characterisation.Read moreRead less
Controlled atomic chaos: breaking through the disorder roadblock for the next generation low power transistors. Computer chip miniaturisation has reached a critical barrier: performance and power consumption are now seriously hampered by atomic level disorder in the materials. The project aims to understand and resolve the disorder problem and establish Australia's place in the international roadmap with disruptive improvement of device speed and power consumption.
Advanced X-ray investigation of atomic and condensed matter science for Australian industry and scientific research. This project aims to improve the precision and calibration of measurements involving X-rays. This in turn will improve outcomes and instrumentation which utilise X-ray sources to probe structures and properties of advanced materials and biological samples.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100151
Funder
Australian Research Council
Funding Amount
$760,000.00
Summary
Probe and engineer interactions in atomic-scale devices with a LT STM. A low-temperature scanning tunnelling microscope: The project aims to establish a facility to exploit the spectroscopic and spatial resolution of an ultra-low temperature scanning tunnelling microscope in conjunction with atomically controlled dopant engineering. In a variety of experiments the research team will explore ultra-scaled transistors, quantum information science devices, and engineered quantum matter. Improving ou ....Probe and engineer interactions in atomic-scale devices with a LT STM. A low-temperature scanning tunnelling microscope: The project aims to establish a facility to exploit the spectroscopic and spatial resolution of an ultra-low temperature scanning tunnelling microscope in conjunction with atomically controlled dopant engineering. In a variety of experiments the research team will explore ultra-scaled transistors, quantum information science devices, and engineered quantum matter. Improving our ability to investigate semiconductor materials at the atomic scale impacts fields ranging from electronics, telecommunication, quantum information to renewable energy research and puts Australia at the forefront of the field of controlled atomic systems in semiconductors.Read moreRead less
ARC Centre of Excellence in Advanced Molecular Imaging. The Centre of Excellence in Advanced Molecular Imaging will innovatively integrate physics, chemistry and biology to unravel the complex molecular interactions that define immunity. The Centre will develop new imaging methods to visualize atomic, molecular and cellular details of how immune proteins interact and
effect immune responses. Outcomes: (i) new technological innovations leading to new imaging methods and products; and (ii) fundame ....ARC Centre of Excellence in Advanced Molecular Imaging. The Centre of Excellence in Advanced Molecular Imaging will innovatively integrate physics, chemistry and biology to unravel the complex molecular interactions that define immunity. The Centre will develop new imaging methods to visualize atomic, molecular and cellular details of how immune proteins interact and
effect immune responses. Outcomes: (i) new technological innovations leading to new imaging methods and products; and (ii) fundamental advances in understanding details of immune responses in health and disease. The Centre will enable Australia to be an international leader in biological imaging, to train next
generation interdisciplinary scientists, and to provide new insights for combating common diseases that afflict society.Read moreRead less