Discovery Early Career Researcher Award - Grant ID: DE140101330
Funder
Australian Research Council
Funding Amount
$376,470.00
Summary
Electron Density - Reactivity Correlation through Experimental Quantum Crystallography. X-ray wavefunction refinement provides a novel approach to the determination of reliable chemical properties through an amalgamation of x-ray diffraction data and ab initio calculations. Detailed knowledge of these properties will greatly improve our understanding of reactivity and selectivity control in chemical processes, two of the most important and challenging questions in chemistry. This project involve ....Electron Density - Reactivity Correlation through Experimental Quantum Crystallography. X-ray wavefunction refinement provides a novel approach to the determination of reliable chemical properties through an amalgamation of x-ray diffraction data and ab initio calculations. Detailed knowledge of these properties will greatly improve our understanding of reactivity and selectivity control in chemical processes, two of the most important and challenging questions in chemistry. This project involves the synthesis of hypercoordinated molecules that serve as sterically frozen intermediates along the pathways of nucleophilic substitution reactions. Comparison of their properties with those of textbook compounds will provide a direct link to the classical Lewis notion of bonding and show that the concept of hypervalency is obsolete.Read moreRead less
Novel hydride complexes for chemical applications. Many main group elements are abundant, cheap, generally less harmful and sometimes even biocompatible compared with most other elements from the periodic table. This project will develop a range of fundamentally important well-defined molecular s-block metal and non-metal hydride complexes and investigate their chemistry and properties. These underdeveloped but emerging compound classes are of significant importance for chemical synthesis, hydro ....Novel hydride complexes for chemical applications. Many main group elements are abundant, cheap, generally less harmful and sometimes even biocompatible compared with most other elements from the periodic table. This project will develop a range of fundamentally important well-defined molecular s-block metal and non-metal hydride complexes and investigate their chemistry and properties. These underdeveloped but emerging compound classes are of significant importance for chemical synthesis, hydrogen storage and catalysis. The results emerging from this project will contribute towards the development of greener and more sustainable technologies.Read moreRead less
New reactivity from unusual main group compounds. This project will develop new, fundamentally important, yet unusual main group compounds and investigate their reactivity. The project will lead to important fundamental advance in main group chemistry and will form the basis for cheaper and cleaner future synthetic methodologies and technologies.
A new era for modern main group chemistry: from landmark molecules towards the replacement of transition metal based technologies. This project will develop innovative approaches to access fascinating chemical compounds that were previously thought incapable of existence. These highly reactive, yet non-toxic systems will be exploited as cheap, environmentally benign replacements for the expensive and toxic metal based chemicals that are currently used in numerous technologies.
Discovery Early Career Researcher Award - Grant ID: DE150100263
Funder
Australian Research Council
Funding Amount
$373,536.00
Summary
Halogen Bonding for Assembly and Separation in Solution. The properties of substances we experience in our daily lives owe much to very weak interactions taking place between molecules. Consider a cup of coffee: very weak interactions hold the water together as a liquid, and result in the biological action of caffeine within the body. The project aims to develop new materials based on an underexplored class of weak interactions known as halogen bonds. These interactions will be used to assemble ....Halogen Bonding for Assembly and Separation in Solution. The properties of substances we experience in our daily lives owe much to very weak interactions taking place between molecules. Consider a cup of coffee: very weak interactions hold the water together as a liquid, and result in the biological action of caffeine within the body. The project aims to develop new materials based on an underexplored class of weak interactions known as halogen bonds. These interactions will be used to assemble large molecules in solution, probe the presence of pollutants in water, and to separate active and inactive forms of pharmaceuticals. The development of health and environmental applications in the course of this project aim to significantly enhance our fundamental understanding of these weak interactions.Read moreRead less