Molecular Electronics Principles and Applications. This project will establish basic conceptual models and computational methods to understand the nature of conduction, memory storage, and solar to electrical energy conversion processes in molecular devices on the 1-nanometer scale. Fundamental research of chemical processes, device interfaces, characterization techniques, and natural photosynthesis will result in widely applicable advances in nanotechnology. Additionally, novel architectures wi ....Molecular Electronics Principles and Applications. This project will establish basic conceptual models and computational methods to understand the nature of conduction, memory storage, and solar to electrical energy conversion processes in molecular devices on the 1-nanometer scale. Fundamental research of chemical processes, device interfaces, characterization techniques, and natural photosynthesis will result in widely applicable advances in nanotechnology. Additionally, novel architectures will be developed for disruptive new technologies in molecular memory and logic design, as well as in the design of biomimetic solar cells. These developments could lead to new Australian electronics industries and an order of magnitude reduction in the production cost of solar electricity.Read moreRead less
A priori simulations of condensed-phase molecular spectroscopy. Molecular spectroscopy is used to probe phenomena in chemistry, biology, and nanoscience, but interpretation of the results often requires simulation of the spectra. While most applications involve condensed phases, until recently most accurate computations could only be performed for gas-phase molecules. Last year, a major advance has started to emerge, stemming from the production of analytical atomic forces for molecules in exc ....A priori simulations of condensed-phase molecular spectroscopy. Molecular spectroscopy is used to probe phenomena in chemistry, biology, and nanoscience, but interpretation of the results often requires simulation of the spectra. While most applications involve condensed phases, until recently most accurate computations could only be performed for gas-phase molecules. Last year, a major advance has started to emerge, stemming from the production of analytical atomic forces for molecules in excited states obtained using density-functional theory. We will adapt these methods to solve fundamental chemical problems involving the intermolecular interactions of molecules that have absorbed light- in particular, hydrogen-bonding interactions in water, studying, eg., chemical solvation and optical damage to DNA.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