The photons take charge: Elucidating the structure and stability of distonic radical anions by mass spectrometry and photoelectron spectroscopy. Recent work has discovered that certain radical anions have electronic configurations that defy chemical convention and exhibit exceptional radical stability. Exploitation of this breakthrough first requires experimental elucidation of the intrinsic electronic structure of these compounds and how it relates to their remarkable properties. This project w ....The photons take charge: Elucidating the structure and stability of distonic radical anions by mass spectrometry and photoelectron spectroscopy. Recent work has discovered that certain radical anions have electronic configurations that defy chemical convention and exhibit exceptional radical stability. Exploitation of this breakthrough first requires experimental elucidation of the intrinsic electronic structure of these compounds and how it relates to their remarkable properties. This project will probe the fundamental structure and energetics of radical anions by modifying instrumentation to enable multi-step gas-phase ion synthesis to be efficiently coupled with anion photoelectron spectroscopy. These investigations are essential to revealing the scope of this phenomenon in free radical chemistry and biology and could inform future development of new catalysts for polymerisation.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120100467
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Unravelling the intrinsic structure and stability of multiply charged anions in the gas-phase using photoelectron spectroscopy and mass spectrometry. Molecules possessing multiple negative charges are common constituents in chemistry, influencing a range of processes ranging from photochemical smog formation to protein structure in vivo. This project will develop new technologies to probe their molecular structure in the gas-phase, leading to a more rigorous understanding of these species.
Development of stable, patterned Self-Assembled Monolayers on carbon for sensors and other nanotechnology applications. Nanotechnology - science at the scale of a billionth of a metre - rests on our ability to manipulate molecules and to build structures that will be part of useful devices. We shall develop new methods to put that chemistry on carbon surfaces - leading to very stable and cheap devices that will have 'real world' applications in environmental monitoring. A 'bottom up' method of f ....Development of stable, patterned Self-Assembled Monolayers on carbon for sensors and other nanotechnology applications. Nanotechnology - science at the scale of a billionth of a metre - rests on our ability to manipulate molecules and to build structures that will be part of useful devices. We shall develop new methods to put that chemistry on carbon surfaces - leading to very stable and cheap devices that will have 'real world' applications in environmental monitoring. A 'bottom up' method of fabrication exploits the ability of similar molecules to line up on a suitable surface, so-called 'self Assembly'. The project is based on sound fundamental science for an applied research outcome and therefore will enhance Australian's standing as a strong scientific country that applies its knowledge at the forefront of technological advancement.Read moreRead less
Formation, photochemistry and fate of gas-phase peroxyl radicals. This project aims to understand how peroxyl radical reactions modulate the composition of air. The gas-phase chemical reactions of organic peroxyl radicals contribute to air quality in clean and polluted environments. However, experimental observations of these reaction intermediates and the complex mechanisms governing their formation and fate are limited. This project will use mass spectrometry and laser-based methods to interro ....Formation, photochemistry and fate of gas-phase peroxyl radicals. This project aims to understand how peroxyl radical reactions modulate the composition of air. The gas-phase chemical reactions of organic peroxyl radicals contribute to air quality in clean and polluted environments. However, experimental observations of these reaction intermediates and the complex mechanisms governing their formation and fate are limited. This project will use mass spectrometry and laser-based methods to interrogate the chemical and photochemical reactions of peroxyl radicals in the gas phase. This project expects to understand the composition and dynamics of the troposphere and inform strategies to improve air quality.Read moreRead less
Rapid, ultra-sensitive protein structure elucidation by mass spectrometry. This project seeks to develop a method for rapidly discovering classes of molecules that bind to unique sites on proteins. The development of new pharmaceuticals is frequently delayed by the time and resources required to identify the sites that new chemical entities bind to protein targets. A recent discovery has resulted in the ability to completely characterise large protein sequences directly from single mass spectra. ....Rapid, ultra-sensitive protein structure elucidation by mass spectrometry. This project seeks to develop a method for rapidly discovering classes of molecules that bind to unique sites on proteins. The development of new pharmaceuticals is frequently delayed by the time and resources required to identify the sites that new chemical entities bind to protein targets. A recent discovery has resulted in the ability to completely characterise large protein sequences directly from single mass spectra. This project aims to leverage this breakthrough by developing a rapid new approach for revealing ligand-protein binding sites using whole-protein mass spectrometry. This would enable novel sites of interactions between molecules and protein targets to be discovered rapidly with high sensitivity. In turn, this would allow the efficient design of next-generation classes of bioactive molecules.Read moreRead less
New laser and mass spectrometry-based tools for comprehensive structural elucidation of lipids and their biomolecular interactions. Lipid-related disorders such as obesity, diabetes and heart disease are reaching epidemic proportions. We propose the development of specialised instrumentation to identify and quantify lipids (fats) in tissue and culture samples thus providing Australian scientists with unique capabilities to investigate the mechanisms of disease.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100059
Funder
Australian Research Council
Funding Amount
$220,000.00
Summary
Multiplexed capabilities for surface analysis and imaging by mass spectrometry. This facility will support research aimed at developing rapid and reliable analytical methods for the detection of chemicals directly from biological and man-made materials. The mass spectroscopy methods used at the facility will reveal molecular-level changes in systems ranging from the lens of the human eye to Colorbond steel® and have applications in the detection of chemical and biological hazards.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346903
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
LC-MS system for Faculty of Sciences, U.N.E. LC-MS is a technique for investigating the composition of complex mixtures and identifying its components. This instrumentation will be utilised at UNE in a diverse range of analytical investigations to further the research aims of scientists in chemistry, biological sciences, archaeology, physics, environmental sciences, marine science as well as biological researchers in specialised units based at UNE. The extraordinarily versatile capacity of this ....LC-MS system for Faculty of Sciences, U.N.E. LC-MS is a technique for investigating the composition of complex mixtures and identifying its components. This instrumentation will be utilised at UNE in a diverse range of analytical investigations to further the research aims of scientists in chemistry, biological sciences, archaeology, physics, environmental sciences, marine science as well as biological researchers in specialised units based at UNE. The extraordinarily versatile capacity of this technique for analysis and identification of organic substances, from small molecules through to large proteins and complex plant and animal metabolites, will provide impetus for existing research and stimulus for new research directions.Read moreRead less