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
In depth characterisation of the gamma delta T cell immune synapse. This project aims to comprehensively characterise the activation principles of gamma delta T cells. These cells have an understudied but central role in vertebrate immunity and development. A missing piece of the puzzle is how gamma delta T cells sense stress and how this signal leads to activation. Expected outcomes include the generation of fundamental knowledge in immunology and structural biology. This proposal uses high-ski ....In depth characterisation of the gamma delta T cell immune synapse. This project aims to comprehensively characterise the activation principles of gamma delta T cells. These cells have an understudied but central role in vertebrate immunity and development. A missing piece of the puzzle is how gamma delta T cells sense stress and how this signal leads to activation. Expected outcomes include the generation of fundamental knowledge in immunology and structural biology. This proposal uses high-skilled techniques, including cryo-electron microscopy and single-molecule imaging and holds ancillary benefits to postgraduate students. Anticipated outcomes include influential publications, building a critical mass of expertise in Australia and fostering international collaborations with Australia at the epicentre.Read moreRead less
Locating Atoms by Observing Crystallographic Phase. Atomic structures are determined by measuring how they scatter radiation. However half of the necessary information, the crystallographic phase, cannot be measured from the scattered intensity. For a century the only option has been to deduce the phase via the statistical analysis of thousands of intensity measurements. This project aims to develop a method to determine atomic structures from the direct observation of phase. From a handful of o ....Locating Atoms by Observing Crystallographic Phase. Atomic structures are determined by measuring how they scatter radiation. However half of the necessary information, the crystallographic phase, cannot be measured from the scattered intensity. For a century the only option has been to deduce the phase via the statistical analysis of thousands of intensity measurements. This project aims to develop a method to determine atomic structures from the direct observation of phase. From a handful of observations and no formal measurements, atoms can be located with picometre precision. It is predicted that this method will be direct, rapid and unequivocal, sensitive to light atoms and applicable to nanostructures, which will represent a paradigm shift in crystallography.Read moreRead less
Multi-Scale Model-Based Simulation of Glass Fragmentation under Blast Loading. It is estimated that most injuries from bomb blasts can be attributed to airborne sharp glass fragments. The proposed project will help us gain better understanding of glass failure mechanism under impact/blast loading. The results from the proposed project are expected to help in developing more effective blast-resistant transparency, ensuring the reliability and quality of buildings and facilities, mitigating injury ....Multi-Scale Model-Based Simulation of Glass Fragmentation under Blast Loading. It is estimated that most injuries from bomb blasts can be attributed to airborne sharp glass fragments. The proposed project will help us gain better understanding of glass failure mechanism under impact/blast loading. The results from the proposed project are expected to help in developing more effective blast-resistant transparency, ensuring the reliability and quality of buildings and facilities, mitigating injury or death due to flying glass fragments, and eventually enhancing public safety and security.Read moreRead less
Understanding and controlling ion-neutral interactions. Australia faces significant environmental and technological challenges including development of clean, sustainable energy sources and technologies that do not adversely affect the terrestrial atmosphere. This project seeks to facilitate a cleaner, greener future through investigations of fundamental chemical interactions responsible for hydrogen storage in solid media, and atmospheric processes responsible for the production and destruction ....Understanding and controlling ion-neutral interactions. Australia faces significant environmental and technological challenges including development of clean, sustainable energy sources and technologies that do not adversely affect the terrestrial atmosphere. This project seeks to facilitate a cleaner, greener future through investigations of fundamental chemical interactions responsible for hydrogen storage in solid media, and atmospheric processes responsible for the production and destruction of ozone. In both cases, the key interactions between ions and neutral molecules will be elucidated through high-resolution laser studies. Ensuing experimental data will play a crucial role in controlling and predicting ion-neutral interactions in technological and environmental contexts.Read moreRead less
Towards a Microscopic Understanding of Anion Solvation. Atomic and molecular anions are ubiquitous components of oceans, rivers, lakes, and the atmosphere, and serve as key participants in natural and industrial chemical processes. In most situations ions are surrounded by a structured sheath of neutral solvent molecules which profoundly affects their physical and chemical properties. Currently, interactions between anions and solvent molecules are poorly understood. In this project we will use ....Towards a Microscopic Understanding of Anion Solvation. Atomic and molecular anions are ubiquitous components of oceans, rivers, lakes, and the atmosphere, and serve as key participants in natural and industrial chemical processes. In most situations ions are surrounded by a structured sheath of neutral solvent molecules which profoundly affects their physical and chemical properties. Currently, interactions between anions and solvent molecules are poorly understood. In this project we will use lasers to probe clusters consisting of just a few molecules attached to an anion, generating information that will enhance our ability to predict and control chemical processes involved in drug design, salination, atmospheric chemistry, and chemical waste remediation.Read moreRead less
Lighting up the charged brigade: laser spectroscopy of protonated and metal-containing complexes. Increasingly, the design of new pharmaceuticals uses computer modeling to account for the shapes of molecules and how they interact with their surroundings. The strongest forces between molecular components are those that involve charged chemical species known as ions. In this project, we will develop advanced laser-based techniques to study in unprecedented detail how molecules respond to the prese ....Lighting up the charged brigade: laser spectroscopy of protonated and metal-containing complexes. Increasingly, the design of new pharmaceuticals uses computer modeling to account for the shapes of molecules and how they interact with their surroundings. The strongest forces between molecular components are those that involve charged chemical species known as ions. In this project, we will develop advanced laser-based techniques to study in unprecedented detail how molecules respond to the presence of nearby charge, or to acquiring charge themselves. Understanding the nature of these attractions, and the structural changes that they induce eventually results in more accurate computer models. This has relevance to fields that include the architecture of proteins, recognition of signaling molecules in the brain, and drug development.Read moreRead less
Origami structures and materials: energy absorption and impact mechanics. This project will devise novel structures and advanced metamaterials to mitigate injury and death from impact or blast loading, using traditional origami folding concepts of design. This technology will have applications to many industries and occupations including vehicle manufacture and the military, as well as personal and public safety. Experiments and advanced numerical simulations will be performed and then analytica ....Origami structures and materials: energy absorption and impact mechanics. This project will devise novel structures and advanced metamaterials to mitigate injury and death from impact or blast loading, using traditional origami folding concepts of design. This technology will have applications to many industries and occupations including vehicle manufacture and the military, as well as personal and public safety. Experiments and advanced numerical simulations will be performed and then analytical models of structural plasticity and impact dynamics will be established to capture the physics involved. The findings will provide an insight into the fundamental mechanics of structures and metamaterials, as well as guidelines for their optimum design.Read moreRead less
Sandwich Structures with Folded Core under Impact and Blast Loading. This project aims to support the development of new materials resistant to impacts. Novel sandwich panels making use of Miura-ori folded cores have superior performance relative to monolithic solid plates, in terms of stiffness and strength. They have great potential to be used in commercial and military vehicles as well as protective structures, which can be subjected to impact and blast loading. This project aims to systemat ....Sandwich Structures with Folded Core under Impact and Blast Loading. This project aims to support the development of new materials resistant to impacts. Novel sandwich panels making use of Miura-ori folded cores have superior performance relative to monolithic solid plates, in terms of stiffness and strength. They have great potential to be used in commercial and military vehicles as well as protective structures, which can be subjected to impact and blast loading. This project aims to systematically investigate the impact and blast response of such sandwich panels by establishing theoretical models and conducting experiments and advanced simulations. The findings may provide an insight into the fundamental mechanics of sandwich panels with folded cores under impact and blast loading, as well as guidelines for optimum design of these novel structures.Read moreRead less
Approaching anion solvation from the bottom up: infrared studies of negatively charged complexes and clusters. We will employ novel spectroscopic strategies to probe the structures of mass-selected anion complexes and clusters in the gas-phase with the purpose of exploring non-covalent forces responsible for anion solvation. The work is motivated by a recognition that anions serve as key participants in a host of natural and industrial chemical processes, and that their physical and chemical pro ....Approaching anion solvation from the bottom up: infrared studies of negatively charged complexes and clusters. We will employ novel spectroscopic strategies to probe the structures of mass-selected anion complexes and clusters in the gas-phase with the purpose of exploring non-covalent forces responsible for anion solvation. The work is motivated by a recognition that anions serve as key participants in a host of natural and industrial chemical processes, and that their physical and chemical properties depend critically upon interactions with solvent molecules. The experimental results should serve as a critical test for computational approaches to describing anion-neutral interactions, and provide new insights into the behaviour of electrolytes, acid-base chemistry, and fundamental bimolecular reactions.Read moreRead less