Reactive Intermediates in Atmospheric and Combustion Chemistry. Reactive intermediates are the key species that determine outcomes of the chemical reaction networks in atmospheric and combustion chemistry. However, most reactive intermediates remain undiscovered. The project aims to discover these intermediates using laser spectroscopy. Current models of atmospheric chemistry cannot account for the carbon balance over forests, nor the formation of secondary organic aerosols. Combustion models st ....Reactive Intermediates in Atmospheric and Combustion Chemistry. Reactive intermediates are the key species that determine outcomes of the chemical reaction networks in atmospheric and combustion chemistry. However, most reactive intermediates remain undiscovered. The project aims to discover these intermediates using laser spectroscopy. Current models of atmospheric chemistry cannot account for the carbon balance over forests, nor the formation of secondary organic aerosols. Combustion models struggle to predict how next-generation fuels burn in modern engines. The successful discovery of these intermediates would allow models to be more accurate and predictive. This will allow scientists, engineers and policy makers to make more informed decisions about atmospheric processes and design more efficient new fuels.Read moreRead less
Double resonance spectroscopy for astrochemistry. We will use advanced laser techniques to probe simulated astrophysical environments with a view to identifying molecules in space. The types of molecules under study are also of direct relevance to other fields such as combustion, and will reveal details of the chemistry of pollution and atmospheres.
A reliable physical model of molecular motion in crystals. The scientific benefits would flow, in the first instance, to the large national and international communities of scientists whose research makes use of the results of X-ray diffraction experiments. Applications of the research to amino acids and peptides will benefit investigations into the structure and molecular dynamics of biological systems, including proteins and enzymes. Studies of charge densities in crystals will obtain a standa ....A reliable physical model of molecular motion in crystals. The scientific benefits would flow, in the first instance, to the large national and international communities of scientists whose research makes use of the results of X-ray diffraction experiments. Applications of the research to amino acids and peptides will benefit investigations into the structure and molecular dynamics of biological systems, including proteins and enzymes. Studies of charge densities in crystals will obtain a standard tool for improved modelling of molecular motion, resulting in physically more realistic charge density functions, and hence greater insight into the relationship between properties of crystals and their constituent molecules.Read moreRead less
Shape-Shifting Molecules: Photoisomerization Action Spectroscopy. This project aims to examine molecules that change shape in response to light in order to gain insight into the biological processes they control. Many biological systems, including the human visual apparatus and bacterial photosynthesis, depend on molecules that change shape in response to light. The project plans to probe shape-shifting molecules with laser light while they are propelled through gas by an electric field. Light-i ....Shape-Shifting Molecules: Photoisomerization Action Spectroscopy. This project aims to examine molecules that change shape in response to light in order to gain insight into the biological processes they control. Many biological systems, including the human visual apparatus and bacterial photosynthesis, depend on molecules that change shape in response to light. The project plans to probe shape-shifting molecules with laser light while they are propelled through gas by an electric field. Light-induced changes in molecular shape produce detectable variations in drift speed. The ensuing knowledge would help calibrate computational approaches for predicting molecular function. It would also establish foundations for understanding essential biological molecules, including retinals, carotenes and peptides, and for developing new light-activated molecular motors and switches.Read moreRead less
The role of low-energy excited states in solar-energy capture. This project aims to determine the nature and role of the lowest-energy excited states in most natural photosynthetic reaction centres and light-harvesting complexes. The lowest-energy states of bacterial reaction centres are critical to function and are used as a paradigm in artificial organic solar-energy capture, but for most photosystems their nature remains unknown. The project aims to answer the critical question of why they do ....The role of low-energy excited states in solar-energy capture. This project aims to determine the nature and role of the lowest-energy excited states in most natural photosynthetic reaction centres and light-harvesting complexes. The lowest-energy states of bacterial reaction centres are critical to function and are used as a paradigm in artificial organic solar-energy capture, but for most photosystems their nature remains unknown. The project aims to answer the critical question of why they do not actually prevent function. It is expected that both the outcomes obtained and techniques developed will be directly relevant to solar-energy device design. The project will apply five existing, complimentary and purposely built spectrometers as well as quantum electronic and nuclear simulation techniques to identify and characterise three key systems.Read moreRead less
Computational studies of melting and the solvation properties of ionic liquids. Ionic liquids are used in industry as green solvents and electrolytes, although there is not yet sufficient knowledge on the science of ionic liquids to enable optimal solvents to be readily designed. This project uses state of the art techniques in computational chemistry to solve practical problems related to the characteristics of ionic liquids.
Ions in the Fire: Laser Spectroscopy of Cryogenically Cooled Molecular Ions. This project will combine sophisticated laser and mass spectrometric techniques to probe the structure and function of cryogenically cooled biological molecules that are the core operational units for vision, photosynthesis and protein labelling. Knowledge gained from the project will be used to calibrate modern computational approaches to describing and predicting molecular function. It is expected that the project wil ....Ions in the Fire: Laser Spectroscopy of Cryogenically Cooled Molecular Ions. This project will combine sophisticated laser and mass spectrometric techniques to probe the structure and function of cryogenically cooled biological molecules that are the core operational units for vision, photosynthesis and protein labelling. Knowledge gained from the project will be used to calibrate modern computational approaches to describing and predicting molecular function. It is expected that the project will provide foundations for understanding and optimising the biological systems upon which life depends, and for developing new light-activated molecular devices including molecular motors, switches and energy harvesting systems.Read moreRead less
Lighting up the charged brigade: laser spectroscopy of protonated and metal-containing complexes. Increasingly, the design of new pharmaceuticals uses computer modeling to account for the shapes of molecules and how they interact with their surroundings. The strongest forces between molecular components are those that involve charged chemical species known as ions. In this project, we will develop advanced laser-based techniques to study in unprecedented detail how molecules respond to the prese ....Lighting up the charged brigade: laser spectroscopy of protonated and metal-containing complexes. Increasingly, the design of new pharmaceuticals uses computer modeling to account for the shapes of molecules and how they interact with their surroundings. The strongest forces between molecular components are those that involve charged chemical species known as ions. In this project, we will develop advanced laser-based techniques to study in unprecedented detail how molecules respond to the presence of nearby charge, or to acquiring charge themselves. Understanding the nature of these attractions, and the structural changes that they induce eventually results in more accurate computer models. This has relevance to fields that include the architecture of proteins, recognition of signaling molecules in the brain, and drug development.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0237958
Funder
Australian Research Council
Funding Amount
$133,000.00
Summary
An enclosive flow Cooling cell for spectroscopic studies. We wish to install a low temperature absorption cell that will be coupled to high resolution spectrometer systems operating in the infrared, visible and ultra-violet regions of the spectrum. This will enable us to further develop techniques for the study of the structures, dynamics and kinetics of molecules of biological and atmospheric significance. This will lead to a better understanding of the structures, dynamics and reaction kinetic ....An enclosive flow Cooling cell for spectroscopic studies. We wish to install a low temperature absorption cell that will be coupled to high resolution spectrometer systems operating in the infrared, visible and ultra-violet regions of the spectrum. This will enable us to further develop techniques for the study of the structures, dynamics and kinetics of molecules of biological and atmospheric significance. This will lead to a better understanding of the structures, dynamics and reaction kinetics of these species and in the case of atmospheric species also provide molecular parameters required for atmospheric monitoring.Read moreRead less
TAILORING OF CARBON MATERIALS FOR USE IN DIRECT CARBON FUEL CELLS. This project aims to develop a fundamental understanding of and methods for tailoring carbon materials to be used in high efficiency (80-85%) direct carbon fuel cells (DCFC). This project addresses an important area in clean and efficient energy supply to meet the World's long-term energy and environmental requirements. Specifically, we aim to focus on the carbon particulates based on carbon black materials with a turbostratic st ....TAILORING OF CARBON MATERIALS FOR USE IN DIRECT CARBON FUEL CELLS. This project aims to develop a fundamental understanding of and methods for tailoring carbon materials to be used in high efficiency (80-85%) direct carbon fuel cells (DCFC). This project addresses an important area in clean and efficient energy supply to meet the World's long-term energy and environmental requirements. Specifically, we aim to focus on the carbon particulates based on carbon black materials with a turbostratic structure, and to investigate the relationship between the microstructures of synthetic carbon black materials and their efficacy in DCFC systems. Ultimately, we aim to engineer novel carbon particulates for use in DCFCs.Read moreRead less