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
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
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
Discovery Early Career Researcher Award - Grant ID: DE130100970
Funder
Australian Research Council
Funding Amount
$370,600.00
Summary
Solar energy conversion: illuminating the origin of long-lived charge-separated states in organic donor/acceptor blends. The origin of exceptionally long-lived charges in organic donor/acceptor solid-state blends will be established. This will substantially enhance the efficiency and commercial viability of applications that rely on these long-lived charge-separated states, such as organic solar cells.
Hot exciton dissociation in donor / acceptor organic solar cells: breaking the efficiency limit of organic photovoltaics. Australia will benefit from this project in several key areas with immediate impact. The development of an innovative solar cell architecture through the use of hot exiton dissociation will deliver a potential increase in the maximum achievable power conversion efficiency. The experimental results will significantly advance fundamental knowledge of organic solar cells. This ....Hot exciton dissociation in donor / acceptor organic solar cells: breaking the efficiency limit of organic photovoltaics. Australia will benefit from this project in several key areas with immediate impact. The development of an innovative solar cell architecture through the use of hot exiton dissociation will deliver a potential increase in the maximum achievable power conversion efficiency. The experimental results will significantly advance fundamental knowledge of organic solar cells. This has significant economic benefits by making these solar cells more affordable and also opening up the opportunity to use new materials unconstrained by existing proprietary interests. The training of personnel will contribute towards solving the biggest challenge facing the solar industry in Australia: lack of skilled personnel in a highly specialised industry.Read moreRead less
How does biodiesel fuel burn? Revealing the chemical processes of methyl ester decomposition and oxidation. It is increasingly likely that a major proportion of the next-generation transport fuels will be derived from biological sources. Biodiesel is already an attractive prospect due to measured reductions in carbon monoxide and fine-particle emission along with its potential as a carbon-neutral fuel source. Impeding the rapid deployment of biodiesel-based engines is our limited understanding o ....How does biodiesel fuel burn? Revealing the chemical processes of methyl ester decomposition and oxidation. It is increasingly likely that a major proportion of the next-generation transport fuels will be derived from biological sources. Biodiesel is already an attractive prospect due to measured reductions in carbon monoxide and fine-particle emission along with its potential as a carbon-neutral fuel source. Impeding the rapid deployment of biodiesel-based engines is our limited understanding of the combustion processes at the molecular level. The purpose of this study is to reveal the underlying chemical processes of biodiesel-droplet burning using laser techniques, synchrotron radiation and mass spectrometry. The ensuing results will flow into modelling studies of biodiesel combustion systems and find practical application by guiding engine design.
Read moreRead less
Gas phase studies of reactive organic radicals: a novel approach using mass spectrometry. Radical reactions play a crucial role in a range of important chemistries, ranging from the formation of photochemical smog to the accumulation of pathogens in the ageing body. Despite their importance, the reactions of many radicals are poorly understood because of current experimental limitations. In this project we propose to develop two new and broadly applicable techniques for probing radical chemistry ....Gas phase studies of reactive organic radicals: a novel approach using mass spectrometry. Radical reactions play a crucial role in a range of important chemistries, ranging from the formation of photochemical smog to the accumulation of pathogens in the ageing body. Despite their importance, the reactions of many radicals are poorly understood because of current experimental limitations. In this project we propose to develop two new and broadly applicable techniques for probing radical chemistry in the gas phase via novel applications of mass spectrometry. Combined with quantum chemical calculations and state-of-the-art thermodynamic measurements these methods will provide a comprehensive understanding of the reactivity of key organic radicals.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100060
Funder
Australian Research Council
Funding Amount
$563,390.00
Summary
Shared picosecond-laser facility. This project aims to extend the Shared Picosecond Laser Facility to include picosecond-pulse technology and to incorporate new consortium members. The Facility, shared among members at four universities and building on over 23 years of collaboration, continues to provide access to state-of-the-art lasers. The Facility will take advantage of its bulk purchasing power to negotiate significant discounts, extended warranties and maintenance contracts. The new lasers ....Shared picosecond-laser facility. This project aims to extend the Shared Picosecond Laser Facility to include picosecond-pulse technology and to incorporate new consortium members. The Facility, shared among members at four universities and building on over 23 years of collaboration, continues to provide access to state-of-the-art lasers. The Facility will take advantage of its bulk purchasing power to negotiate significant discounts, extended warranties and maintenance contracts. The new lasers will enable access to picosecond timescales and facilitate complex multi-laser experiments in a wide variety of projects including reaction dynamics, materials chemistry and photovoltaics.Read moreRead less