Studies on metal dusting : reaction mechanisms and their control. Gases which are supersaturated with carbon can react at high temperatures with steels and nickel-base alloys to destroy them, producing a dust of carbon plus metal and/or metal carbides. The mechanism is not properly understood, and the rate of the process impossible to predict. This program will dissect the mechanism using kinetic studies and electron microscopy of precisely located parts of the reacting system. Ways of controll ....Studies on metal dusting : reaction mechanisms and their control. Gases which are supersaturated with carbon can react at high temperatures with steels and nickel-base alloys to destroy them, producing a dust of carbon plus metal and/or metal carbides. The mechanism is not properly understood, and the rate of the process impossible to predict. This program will dissect the mechanism using kinetic studies and electron microscopy of precisely located parts of the reacting system. Ways of controlling the process via alloy compositional changes will be explored.Read moreRead less
"Metal dusting" of austenitic alloys: mechanisms and interventions. "Metal dusting" is a catastrophic form of metal corrosion which we do not yet understand. It affects industries important to Australia: reforming of natural gas and (potentially) ceramic oxide fuel cells. This project aims to understand the process of austenitic alloy dusting, and thereby design materials to resist this form of attack. This will allow new natural gas processing industries in Australia to be internationally compe ...."Metal dusting" of austenitic alloys: mechanisms and interventions. "Metal dusting" is a catastrophic form of metal corrosion which we do not yet understand. It affects industries important to Australia: reforming of natural gas and (potentially) ceramic oxide fuel cells. This project aims to understand the process of austenitic alloy dusting, and thereby design materials to resist this form of attack. This will allow new natural gas processing industries in Australia to be internationally competitive.
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Controlling corrosion of steel by carbon dioxide-rich gases at high temperatures. A growing difficulty for Australia is the need to reduce carbon dioxide (CO2) emissions whilst maintaining the economic advantages of coal fired power stations. Technologies for capturing CO2 from these stations are being developed, but inevitably involve the need to handle hot CO2-rich gases. These are surprisingly corrosive to the materials of which power stations are constructed, in a way which is not fully unde ....Controlling corrosion of steel by carbon dioxide-rich gases at high temperatures. A growing difficulty for Australia is the need to reduce carbon dioxide (CO2) emissions whilst maintaining the economic advantages of coal fired power stations. Technologies for capturing CO2 from these stations are being developed, but inevitably involve the need to handle hot CO2-rich gases. These are surprisingly corrosive to the materials of which power stations are constructed, in a way which is not fully understood. This project aims to achieve this understanding, and to provide the basis for future alloy design.Read moreRead less
Advanced high strength steels produced by energy efficient direct strip casting. Over one billion tonnes of steel is produced every year and one method of reducing the environmental footprint of this production is through strip casting. This process reduces the energy required to process liquid steel into thin sheet product by an astounding 90 per cent. This proposal aims to expand the application of this technology to new steel grades.
Designing starches for increased productivity in mineral flotation. Designing starches for increased productivity in mineral flotation. This project aims to understand the process of starch-mineral surface interactions, and design and develop tailored starch depressant/flocculant biopolymers for mineral beneficiation via the froth flotation process. Natural and modified starches are used as depressants and flocculants in mineral flotation, but scientists lack knowledge of mechanisms describing s ....Designing starches for increased productivity in mineral flotation. Designing starches for increased productivity in mineral flotation. This project aims to understand the process of starch-mineral surface interactions, and design and develop tailored starch depressant/flocculant biopolymers for mineral beneficiation via the froth flotation process. Natural and modified starches are used as depressants and flocculants in mineral flotation, but scientists lack knowledge of mechanisms describing starch-mineral surface interactions, particularly how they process base metal sulphides. This project also intends to develop starch characterisation techniques and novel methods for modifying starch structures and functionalities. Anticipated outcomes are new novel manufacturing applications for starch in Australia.Read moreRead less
New Approaches to Understanding Grain Boundary Chemistry. This project will provide a fundamentally better understanding of the relationship between grain boundary segregation and the recrystallisation behaviour of steel and Al alloys. This knowledge will lead to more efficient thermomechanical processing techniques, which will be of benefit to Australia's steel and light alloy industries. The experimental techniques to be developed will be the first of their kind. They have enormous potential f ....New Approaches to Understanding Grain Boundary Chemistry. This project will provide a fundamentally better understanding of the relationship between grain boundary segregation and the recrystallisation behaviour of steel and Al alloys. This knowledge will lead to more efficient thermomechanical processing techniques, which will be of benefit to Australia's steel and light alloy industries. The experimental techniques to be developed will be the first of their kind. They have enormous potential for use in future segregation studies of other alloy systems and are expected to make a major contribution to fundamental and applied research over the next few years.Read moreRead less
Effect of Chromium and Manganese on the Formations of Graphite and Carbide on the surface of Low Carbon Sheet Steels. Surface graphite and surface carbide are two surface defects observed in cold-rolled low carbon steel sheets after batch annealing under non-oxidising atmosphere. The surface defects detract from the appearance of the steel sheets and diminish the surface treatment potential of the sheets, causing significant and costly material losses. The aims of the project are to study the in ....Effect of Chromium and Manganese on the Formations of Graphite and Carbide on the surface of Low Carbon Sheet Steels. Surface graphite and surface carbide are two surface defects observed in cold-rolled low carbon steel sheets after batch annealing under non-oxidising atmosphere. The surface defects detract from the appearance of the steel sheets and diminish the surface treatment potential of the sheets, causing significant and costly material losses. The aims of the project are to study the inhibition of surface graphite formation by the additions of Chromium and Manganese and to study the mechanism of formation of surface carbide with the aim of developing an alloying / processing strategy which eliminates both the surface graphite and the surface carbide.Read moreRead less
Role of oxide grain boundaries in controlling high temperature corrosion of steels by carbon dioxide-rich gases. Advanced coal combustion technologies make carbon dioxide capture possible, but require improved materials to handle hot carbon dioxide-rich gases. These gases are surprisingly corrosive and the corrosion process is not fully understood. This project aims to achieve this understanding and to provide the basis for future alloy design.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100115
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
High-temperature probes for investigating phase transitions and reaction kinetics in thin films, nanostructured materials and biomaterials. This infrastructure for high temperature surface analysis and in-situ diagnostics as a function of temperature and gas environments will enhance Australia's capabilities in creating new materials for devices that will meet needs in medical, communications, environmental and security applications. The facility will enable researchers to understand and exploi ....High-temperature probes for investigating phase transitions and reaction kinetics in thin films, nanostructured materials and biomaterials. This infrastructure for high temperature surface analysis and in-situ diagnostics as a function of temperature and gas environments will enhance Australia's capabilities in creating new materials for devices that will meet needs in medical, communications, environmental and security applications. The facility will enable researchers to understand and exploit interfacial phenomena and to tailor processing-microstructure-composition correlations, so as to design new materials with the best performance possible. Probes with unique capabilities will measure surface morphology, optical properties, elemental composition and crystallographic phase.The facility will be the first in Australia to offer a comprehensive study of structure and properties at high temperature.Read moreRead less
Optimisation of Nanostructure in new Microalloyed Strip Cast Steels for Control of Properties. Australia is an internationally competitive producer of steel and stands to benefit from the improvements in steel design made possible by a more fundamental understanding of the relationship between steel nanostructure and steel properties and performance. Using targeted microalloying additions, this project aims to develop a new class of strip cast steels that can serve entirely new applications and ....Optimisation of Nanostructure in new Microalloyed Strip Cast Steels for Control of Properties. Australia is an internationally competitive producer of steel and stands to benefit from the improvements in steel design made possible by a more fundamental understanding of the relationship between steel nanostructure and steel properties and performance. Using targeted microalloying additions, this project aims to develop a new class of strip cast steels that can serve entirely new applications and so open up new market growth opportunities in Australia's manufacturing industry. This research falls under the national research priority 'Frontier Technologies for Transforming Australian Industry'.Read moreRead less