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
The long-term impact of short-lived, fluorinated pollutants. In 1987, the Montreal Protocol has regulated the manufacture and use of compounds that deplete the ozone layer. Industry has innovated to produce new compounds that do not affect ozone levels, for use in refrigeration and other applications for modern society. We have discovered that the current generation of compounds called hydrofluoroolefins decompose in the atmosphere to produce the worst global warming gas known. We hypothesise th ....The long-term impact of short-lived, fluorinated pollutants. In 1987, the Montreal Protocol has regulated the manufacture and use of compounds that deplete the ozone layer. Industry has innovated to produce new compounds that do not affect ozone levels, for use in refrigeration and other applications for modern society. We have discovered that the current generation of compounds called hydrofluoroolefins decompose in the atmosphere to produce the worst global warming gas known. We hypothesise that other HFOs will also decay into global warming compounds. In this project we will determine the atmospheric consequences of modern refrigerants. Expected benefits include determination the best and worst compounds for environmental impact, and data to guide industry and legislators.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100549
Funder
Australian Research Council
Funding Amount
$384,616.00
Summary
The true impact of fluorinated compounds in the atmosphere. This project aims to improve the underpinning science that is incorporated into atmospheric chemistry models so humanity can better understand, predict and respond to the impact of emitting large volumes of fluorinated compounds. This project expects to challenge assumptions currently used to model the atmospheric chemistry of organic fluorine compounds, as well as to evaluate the environmental impact of replacements. Expected outcomes ....The true impact of fluorinated compounds in the atmosphere. This project aims to improve the underpinning science that is incorporated into atmospheric chemistry models so humanity can better understand, predict and respond to the impact of emitting large volumes of fluorinated compounds. This project expects to challenge assumptions currently used to model the atmospheric chemistry of organic fluorine compounds, as well as to evaluate the environmental impact of replacements. Expected outcomes include a general model of organic fluorine photochemistry and refined atmospheric chemistry models. This should provide significant benefits in that humanity can avoid an environmental disaster and new, environmentally benign products can be developed.Read moreRead less
Promoting new reaction pathways with nonequilibrium flow. This project aims to develop a fundamental molecular level understanding of flow-induced physical and chemical reactions in liquids. Nonequilibrium molecular dynamics simulations will be used to gain insight into the mechanisms that promote reactions under shear, and how these are related to molecular structure and fluid composition. New relationships for determination of rate constants of reactions in nonequilibrium systems will also be ....Promoting new reaction pathways with nonequilibrium flow. This project aims to develop a fundamental molecular level understanding of flow-induced physical and chemical reactions in liquids. Nonequilibrium molecular dynamics simulations will be used to gain insight into the mechanisms that promote reactions under shear, and how these are related to molecular structure and fluid composition. New relationships for determination of rate constants of reactions in nonequilibrium systems will also be developed and tested. It is expected that this knowledge will enhance the capacity to control and promote reactions. This is significant for advancement of many technologies, from development of new synthetic pathways and products, to design of lubricants that can withstand extreme strain rates.Read moreRead less
High-productivity ammonia electrosynthesis. The aim of this project is to develop and demonstrate high-performance devices for ammonia production from renewables by a scalable electrolysis method. This will be achieved by experimental and modelling investigations of the nitrogen reduction reaction to guide the design of tailor-made cathodes. New knowledge in catalysis and materials science is expected to be generated. The target outcome of the project is a sustainable and affordable ammonia synt ....High-productivity ammonia electrosynthesis. The aim of this project is to develop and demonstrate high-performance devices for ammonia production from renewables by a scalable electrolysis method. This will be achieved by experimental and modelling investigations of the nitrogen reduction reaction to guide the design of tailor-made cathodes. New knowledge in catalysis and materials science is expected to be generated. The target outcome of the project is a sustainable and affordable ammonia synthesis method as an alternative to the current fossil-fuels-based and excessively greenhouse-emitting process. The technology to be developed in this project is anticipated to be of significant benefit to the Australian agriculture sector as a local, on-demand source of low-cost fertilisers.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100163
Funder
Australian Research Council
Funding Amount
$411,000.00
Summary
Harnessing dynamic materials to produce better heterogeneous catalysts. This project aims to investigate an emerging class of catalysts featuring dynamic reaction sites using innovative computational chemistry methods. The capability of traditional materials has reached a performance status quo for many catalytic reactions. Dynamic materials may unlock a new dimension in catalyst design; however, their influence on reactivity is unclear, and the combination of materials and dynamics represents a ....Harnessing dynamic materials to produce better heterogeneous catalysts. This project aims to investigate an emerging class of catalysts featuring dynamic reaction sites using innovative computational chemistry methods. The capability of traditional materials has reached a performance status quo for many catalytic reactions. Dynamic materials may unlock a new dimension in catalyst design; however, their influence on reactivity is unclear, and the combination of materials and dynamics represents an immense parameter space. This project expects to provide a comprehensive framework for understanding dynamic catalytic processes. Expected outcomes of this project include the identification of specific materials and dynamics that achieve extraordinary efficiency for the benefit of sustainable chemical production.Read moreRead less
A coordinate-independent theory for multi-time-scale dynamical systems. Biochemical reaction networks operate inherently on many disparate timescales, and identifying this temporal hierarchy is key to understanding biological behaviour. Currently, the existing dynamical systems theory is not able to rigorously analyse many important biological systems and networks due to this inherent non-standard multi-time-scale splitting. This project aims to remove these stumbling blocks and develop a coordi ....A coordinate-independent theory for multi-time-scale dynamical systems. Biochemical reaction networks operate inherently on many disparate timescales, and identifying this temporal hierarchy is key to understanding biological behaviour. Currently, the existing dynamical systems theory is not able to rigorously analyse many important biological systems and networks due to this inherent non-standard multi-time-scale splitting. This project aims to remove these stumbling blocks and develop a coordinate-independent mathematical theory that weaves together results from geometric singular perturbation theory, differential and algebraic geometry and reaction network theory to decompose and explain the structure in the dynamic hierarchy of events in non-standard multi-time-scale systems and networks.Read moreRead less