A Novel Approach to Grain Refinement of Cast Metals. This proposal combines fundamental scientific studies with applied engineering research. The outcomes will offer materials scientists and engineers with a totally new way to understand the grain refinement of cast metals. The new scientific knowledge generated will put Australia at the absolute forefront of the field and maintain our internationally leading position. The new grain refiners and the relevant master alloys to be developed will ....A Novel Approach to Grain Refinement of Cast Metals. This proposal combines fundamental scientific studies with applied engineering research. The outcomes will offer materials scientists and engineers with a totally new way to understand the grain refinement of cast metals. The new scientific knowledge generated will put Australia at the absolute forefront of the field and maintain our internationally leading position. The new grain refiners and the relevant master alloys to be developed will have strong potential to be commercialized to produce cast metals with much improved properties and performance. This will not only increase Australian competitive ability in the international market, but will also make considerable economic benefits.Read moreRead less
The Development of High Strength Aluminium and Magnesium Alloys Using "Edge-to-edge" Matching Model. The theoretical, crystallographic "edge-to-edge" matching model for diffusion-controlled phase transformations will be applied to the practical development of improved industrial aluminium and magnesium alloys with assistance of computer simulations. The model will be used to enhance the precipitation hardening response and to identify more effective grain refiners in these light alloys. The aim ....The Development of High Strength Aluminium and Magnesium Alloys Using "Edge-to-edge" Matching Model. The theoretical, crystallographic "edge-to-edge" matching model for diffusion-controlled phase transformations will be applied to the practical development of improved industrial aluminium and magnesium alloys with assistance of computer simulations. The model will be used to enhance the precipitation hardening response and to identify more effective grain refiners in these light alloys. The aims will be the development of one high strength aluminium alloy with good ductility and one high strength magnesium alloy with good creep resistance at elevated temperatures. A computer program that will help to identify the most effective grain refiners for specific light alloys will also be produced.Read moreRead less
New Mg-based hydrogen storage material with destabilised hydrides. This project will develop a new magnesium-based hydrogen storage material for applications such as hydrogen-powered automobiles. Clean energy is a global challenge to reduce greenhouse emissions. Safe storage of hydrogen is a key barrier to the widespread implementation of hydrogen as a clean energy carrier. Magnesium is amongst the few materials able to meet the requirements for effective, safe, light-weight and cheap hydrogen s ....New Mg-based hydrogen storage material with destabilised hydrides. This project will develop a new magnesium-based hydrogen storage material for applications such as hydrogen-powered automobiles. Clean energy is a global challenge to reduce greenhouse emissions. Safe storage of hydrogen is a key barrier to the widespread implementation of hydrogen as a clean energy carrier. Magnesium is amongst the few materials able to meet the requirements for effective, safe, light-weight and cheap hydrogen storage. Light metals is a priority area for Australia with our large resources of aluminium and magnesium. Magnesium-based hydrogen storage could create a huge market for Australian magnesium and hydrogen storage systems. Read moreRead less