Photodissociation Dynamics of Radicals and Molecules. Photodissociation dynamics involves studying fundamental chemical processes that underpin all chemical reactivity. We address three of the important unanswered questions in this field: i) how do the lessons learned from small molecules transfer to larger molecules? ii) can one control chemical reactivity by selecting specific states of the reactant?; and iii) are the dynamics of radicals fundamentally different to stable molecules? We wi ....Photodissociation Dynamics of Radicals and Molecules. Photodissociation dynamics involves studying fundamental chemical processes that underpin all chemical reactivity. We address three of the important unanswered questions in this field: i) how do the lessons learned from small molecules transfer to larger molecules? ii) can one control chemical reactivity by selecting specific states of the reactant?; and iii) are the dynamics of radicals fundamentally different to stable molecules? We will combine expertise in large molecule spectroscopy and photodissociation dynamics with technology in radical production to provide insight into these fundamental questions. Photodissociation dynamics is firmly embedded in photon science and technology.Read moreRead less
Energetics and dynamics of solvated biologically relevant molecules using liquid microjet and ion imaging technologies. The shape of many biomolecules in solution plays a critical role in determining their biological activity and function. It is known that the bonds that form between the biomolecules and the water solvent control this shape. However, very little is known about the strength and structure of these bonds at different sites around the biomolecule. Many experiments have informed u ....Energetics and dynamics of solvated biologically relevant molecules using liquid microjet and ion imaging technologies. The shape of many biomolecules in solution plays a critical role in determining their biological activity and function. It is known that the bonds that form between the biomolecules and the water solvent control this shape. However, very little is known about the strength and structure of these bonds at different sites around the biomolecule. Many experiments have informed us about the strength of the bonds, others have told us where the bonds occur. This project will provide both pieces of information for the first time, allowing us to better understand, and therefore control, biological function. This work will assist in the development of new biotechnology processes, especially in the emerging area of proteomics.Read moreRead less
Laser Spectroscopic Studies of Non-Covalent Solute-Solvent Interactions Involving Non-Volatile Biomolecules in the Gas Phase. Solute-solvent interactions play a critical role in determining whether or not many biomolecules display biological activity in solution. Making use of our novel liquid microjet injection technology, we will generate micro-solvated gas phase biomolecules by rapid laser desorption from the surface of a liquid jet (here, micro-solvation describes up to ~10 solvent molecule ....Laser Spectroscopic Studies of Non-Covalent Solute-Solvent Interactions Involving Non-Volatile Biomolecules in the Gas Phase. Solute-solvent interactions play a critical role in determining whether or not many biomolecules display biological activity in solution. Making use of our novel liquid microjet injection technology, we will generate micro-solvated gas phase biomolecules by rapid laser desorption from the surface of a liquid jet (here, micro-solvation describes up to ~10 solvent molecules attached to a solute). Following desorption, laser spectroscopy will be used to directly characterise the non-volatile biomolecular solute-solvent topography. This project will create a new application of laser science to study biophysical and biochemical processes that remain difficult, if not impossible, to explore using traditional techniques.Read moreRead less
Improving explosive emulsions by understanding surfactant interactions. This project will design new surfactants that will lead to more cost effective, stable and reliable explosive emulsions. The pressure required to force dispersed phase droplets to coalesce will be measured both directly and by osmotic stress. These parameters have not previously been measured for an inverse emulsion system. The measurements made will be correlated to the structure of the stabilising surfactant enabling new a ....Improving explosive emulsions by understanding surfactant interactions. This project will design new surfactants that will lead to more cost effective, stable and reliable explosive emulsions. The pressure required to force dispersed phase droplets to coalesce will be measured both directly and by osmotic stress. These parameters have not previously been measured for an inverse emulsion system. The measurements made will be correlated to the structure of the stabilising surfactant enabling new and more effective surfactants to be designed.Read moreRead less
Bubble Stabilization and Density Control in Self-Supporting Explosive Emulsions. The mining industry in Australia employs about 70,000 people and has a total sales and service income of about $55B. Most mining outputs are commodities and a reduction in cost is the primary method of increasing market share. DNAP is a major supplier of explosive services to mines that produce coal, iron ore and gold for export. The work in this project will lead to more efficient explosives emulsions and allow mi ....Bubble Stabilization and Density Control in Self-Supporting Explosive Emulsions. The mining industry in Australia employs about 70,000 people and has a total sales and service income of about $55B. Most mining outputs are commodities and a reduction in cost is the primary method of increasing market share. DNAP is a major supplier of explosive services to mines that produce coal, iron ore and gold for export. The work in this project will lead to more efficient explosives emulsions and allow mining tolower total cost per unit sold. Such improvements in mining efficiencies will have a direct impact of the selling price of the product. Increased export earnings and a greater number of people employed in the industry would be direct results of the successful completion of the work proposed.Read moreRead less
Roaming around the Transition State: A New Mechanism of Chemical Reactions. Gas-phase reaction mechanisms are at the core of some of the most important problems facing Australia at present: atmospheric models for CO2 are central to climate change; models of isotope exchange are essential to learn about past climates from Antarctic ice cores; and models of combustion are used to optimise energy efficiency. The mechanisms used in these models rely on accurate chemistry. A newly discovered chemica ....Roaming around the Transition State: A New Mechanism of Chemical Reactions. Gas-phase reaction mechanisms are at the core of some of the most important problems facing Australia at present: atmospheric models for CO2 are central to climate change; models of isotope exchange are essential to learn about past climates from Antarctic ice cores; and models of combustion are used to optimise energy efficiency. The mechanisms used in these models rely on accurate chemistry. A newly discovered chemical mechanism has the potential to change many of the reactions that we currently use in these chemical models. This project will determine how important this new mechanism is, and what its impact is on gas-phase reaction models.Read moreRead less
Redox processes in Bayer liquors. Alumina, and the aluminium produced from it, are amongst Australia's most important mineral commodities, earning about $8 billion p.a. in exports. However, ongoing technological improvements are needed for Australian producers to remain globally competitive. This project addresses a key problem in alumina production - the behaviour of organic impurities - which will help to increase industrial productivity and reduce energy consumption. Insights gained from this ....Redox processes in Bayer liquors. Alumina, and the aluminium produced from it, are amongst Australia's most important mineral commodities, earning about $8 billion p.a. in exports. However, ongoing technological improvements are needed for Australian producers to remain globally competitive. This project addresses a key problem in alumina production - the behaviour of organic impurities - which will help to increase industrial productivity and reduce energy consumption. Insights gained from this research will also minimize the environmental and occupational health impacts of various process emissions, making the industry more sustainable.Read moreRead less
New laser and mass spectrometry methods for detecting protonation isomers. Mass spectrometry is a major tool for the detection of molecules for understanding disease, pollution control and chemical synthesis. However, intricate differences in molecular structure - vital to chemical function - can confuse detection methods leading to false negatives. This is especially problematic for complex biological samples. Recent breakthroughs in laser-based mass spectrometry methods, combined with ion mobi ....New laser and mass spectrometry methods for detecting protonation isomers. Mass spectrometry is a major tool for the detection of molecules for understanding disease, pollution control and chemical synthesis. However, intricate differences in molecular structure - vital to chemical function - can confuse detection methods leading to false negatives. This is especially problematic for complex biological samples. Recent breakthroughs in laser-based mass spectrometry methods, combined with ion mobility, now allow detection of subtle yet important structural features. This project aims to exploit these advances by developing new instrumentation and protocols with these enhanced capabilities thus accelerating advances in automated mass spectrometry, improved antibiotic detection and complex biomolecule screening.Read moreRead less
Operating Mechanisms and Dynamics of Molecular Motors. This project will enhance the nation's expertise in nanotechnology which is emerging as an important enabling technology for the creation of sophisticated novel materials. It is in the national interest to be at the forefront of this field because of its great potential for economic advantage such as the creation of new valued-added export industries based on "bottom-up" fabrication.
Application and Evaluation of New Phase Change Materials in Textiles for Minimization of Heat Stress in Elite Athletes. Elite athletes experience heat stress during endurance events as they reach natural barriers of heat dissipation and thermal regulation. These stresses limit performance and present severe psychological challenges. Research showing that cooling body temperatures prior to competition can increase performance led the Australian Institute of Sport to develop ice jackets during the ....Application and Evaluation of New Phase Change Materials in Textiles for Minimization of Heat Stress in Elite Athletes. Elite athletes experience heat stress during endurance events as they reach natural barriers of heat dissipation and thermal regulation. These stresses limit performance and present severe psychological challenges. Research showing that cooling body temperatures prior to competition can increase performance led the Australian Institute of Sport to develop ice jackets during the 1990s. Our project will develop a new generation of athlete garments embedded with phase change materials that provide efficient cooling during competition, without the disadvantages of ice chilling. These novel materials may provide a competitive edge under the extreme conditions expected at the Athens Olympics and beyond.Read moreRead less