Predicting Environmental Effects on Structure and Reactivity. This project tackles one of the most important and fundamental problems in theoretical chemistry: solvent effects on chemical reactions. The new methods and computer programs generated will be freely available to the Australian (and international) scientific communitities and will further enhance Australia's strong reputation in Theoretical Chemistry.
The applications chosen will allow new technologies in biosensing and strategies in ....Predicting Environmental Effects on Structure and Reactivity. This project tackles one of the most important and fundamental problems in theoretical chemistry: solvent effects on chemical reactions. The new methods and computer programs generated will be freely available to the Australian (and international) scientific communitities and will further enhance Australia's strong reputation in Theoretical Chemistry.
The applications chosen will allow new technologies in biosensing and strategies in computational drug design to be investigated. This will benefit the Australian biotechnology and pharmaceutical industries and may substantially aid in understanding the mechanism and treatment of disease. Read moreRead less
Process Chemistry for Distributed Manufacture of Nitric Acid. This project will benefit Australia by enabling a new approach to the manufacture of explosives for the country's mining industry which will provide the entire explosives supply chain with greater safety and security. Development of this technology will enhance Orica's competitive position as the largest manufacturer of mining explosives in the world and will produce wealth for the country through the continued success of this ASX Top ....Process Chemistry for Distributed Manufacture of Nitric Acid. This project will benefit Australia by enabling a new approach to the manufacture of explosives for the country's mining industry which will provide the entire explosives supply chain with greater safety and security. Development of this technology will enhance Orica's competitive position as the largest manufacturer of mining explosives in the world and will produce wealth for the country through the continued success of this ASX Top 50 company and the export of the technology.Read moreRead less
Chemistry at the threshold: unusual mechanisms and unexpected products. The chemical processes in combustion and in the atmosphere are complex and understood incompletely; for example 30-60 million tonnes of acids in the atmosphere are unaccounted for. The project will measure and model three new chemical processes that may account for the atmospheric acids, and other unexplained occurrences in combustion chemistry.
Atmospheric photochemistry - it's a lot more complicated than we thought. The project plans to develop a more accurate model of the changing atmosphere. The chemical composition of Earth’s atmosphere is changing because of anthropogenic activities. Predicting the consequences of this change requires accurate chemical models. The hydroxyl radical (OH) is the most important radical in the atmosphere, yet atmospheric models predict its concentration in forested regions to be about 10 times lower th ....Atmospheric photochemistry - it's a lot more complicated than we thought. The project plans to develop a more accurate model of the changing atmosphere. The chemical composition of Earth’s atmosphere is changing because of anthropogenic activities. Predicting the consequences of this change requires accurate chemical models. The hydroxyl radical (OH) is the most important radical in the atmosphere, yet atmospheric models predict its concentration in forested regions to be about 10 times lower than measured. These models also predict the amount of organic acids to be lower than measured. This project hypothesises two new chemical processes to account for these discrepancies. Photo-isomerisation of carbonyls to enols is suggested to be a source of organic acids. Reaction of extraordinarily hot carbonyl photofragments with oxygen is hypothesised to be an important source of OH radicals.Read moreRead less
Molecular signatures of complex photodissociation reactions. All energy on earth comes from the sun, either directly (e.g photosynthesis) or indirectly (e.g fossil fuels). Photochemistry is the study of how this light is absorbed and what happens to a molecule afterwards. Despite significant experimental and theoretical advances in the past decade (some in our lab), scientists still cannot predict the outcomes of most photochemical reactions. In this project we will determine the reactivity o ....Molecular signatures of complex photodissociation reactions. All energy on earth comes from the sun, either directly (e.g photosynthesis) or indirectly (e.g fossil fuels). Photochemistry is the study of how this light is absorbed and what happens to a molecule afterwards. Despite significant experimental and theoretical advances in the past decade (some in our lab), scientists still cannot predict the outcomes of most photochemical reactions. In this project we will determine the reactivity of several small, fundamental organic molecules. Not only are these molecules pollutants around our cities, but discovery of how they react in the presence of light will allow us to understand and predict the photochemistry of a much wider range of organic species.Read moreRead less
Helium droplets: a nanoscale laboratory for studying intermolecular bonding and chemical reactivity. This type of research requires a rather complicated apparatus capable of creating a stream of helium droplets, embedding molecules and interrogating their properties using laser spectroscopy. The apparatus built in Sydney is the only one capable of this in Australia and using this new apparatus we will create many novel, bizarre and intriguing aggregates of molecules and atoms. The project involv ....Helium droplets: a nanoscale laboratory for studying intermolecular bonding and chemical reactivity. This type of research requires a rather complicated apparatus capable of creating a stream of helium droplets, embedding molecules and interrogating their properties using laser spectroscopy. The apparatus built in Sydney is the only one capable of this in Australia and using this new apparatus we will create many novel, bizarre and intriguing aggregates of molecules and atoms. The project involves cutting-edge scientific methods and will shift the boundaries of can-do science in the laser laboratory at the University of Sydney and in Australia in general.Read moreRead less
Atmospheric Photothermal Oxidation as a New Reaction in the Atmosphere. Atmospheric models provide crucial advice on the current and future impacts of human activity on the atmosphere. This project hypothesizes the presence of a new class of chemical reactions that are unknown in atmospheric science and therefore missing from the best existing models. The reactions require both sunlight and air, and they behave differently to all other types of atmospheric reactions. This project aims to charact ....Atmospheric Photothermal Oxidation as a New Reaction in the Atmosphere. Atmospheric models provide crucial advice on the current and future impacts of human activity on the atmosphere. This project hypothesizes the presence of a new class of chemical reactions that are unknown in atmospheric science and therefore missing from the best existing models. The reactions require both sunlight and air, and they behave differently to all other types of atmospheric reactions. This project aims to characterise these reactions in the lab, understand them with theory, and quantify their global impact through modelling. Expected benefits include new understanding of atmospheric chemistry, more accurate model predictions, and—as a result—better strategies for managing the impacts of human activity on the environment.Read moreRead less
Design of reactive foils for joining amorphous alloys. Amorphous alloys or metallic glasses are special materials that retain the random structure of a liquid but in a solid form. They can show special properties of very high strength, toughness and corrosion resistance. The enormous difficulty in joining amorphous alloys to make larger assemblies is greatly curbing their uptake in technology. In this research, state of the art experimental and computational tools will be used to investigate the ....Design of reactive foils for joining amorphous alloys. Amorphous alloys or metallic glasses are special materials that retain the random structure of a liquid but in a solid form. They can show special properties of very high strength, toughness and corrosion resistance. The enormous difficulty in joining amorphous alloys to make larger assemblies is greatly curbing their uptake in technology. In this research, state of the art experimental and computational tools will be used to investigate the extremely fast high temperature reactions occurring in reactive foils of layered metals which, when inserted at the proposed join and ignited, quickly produce a bond. The research will lay the foundation for a robust and reliable means for joining amorphous alloys by means of reactive foils. Read moreRead less