Synthetic and theoretical studies of metal complexes containing carbon-rich ligands. Previous studies in my group, in conjunction with synthetic and theoretical chemistry groups at the Université de Rennes 1, France, have delineated the properties of a series of complexes containing carbon chains linking two metal centres. Having achieved a partial understanding of the features which result in good electronic communication between the metal centres via the carbon chain, the present proposal see ....Synthetic and theoretical studies of metal complexes containing carbon-rich ligands. Previous studies in my group, in conjunction with synthetic and theoretical chemistry groups at the Université de Rennes 1, France, have delineated the properties of a series of complexes containing carbon chains linking two metal centres. Having achieved a partial understanding of the features which result in good electronic communication between the metal centres via the carbon chain, the present proposal seeks to extend this collaboration to further studies which will generate related compounds in which actual eletron exchange can occur, i.e. leading to oxidation/reduction, by using compounds in which two or more different metal centres are present. This may lead to development of nano devices, e.g. molecular-scale switches. If one of the centres is activated by light, a photo-active sensor may result.Read moreRead less
Harnessing light and electricity to drive chemical synthesis. This project will explore and establish original strategies that use inputs of energy (light and electricity) to break or form chemical bonds, which can provide new or improved access to valuable compounds. In this way, this research will augment or enhance existing methods for the selective and direct manipulation of molecules by creating tools that allow chemists to prepare molecules under particularly mild conditions. The outcomes ....Harnessing light and electricity to drive chemical synthesis. This project will explore and establish original strategies that use inputs of energy (light and electricity) to break or form chemical bonds, which can provide new or improved access to valuable compounds. In this way, this research will augment or enhance existing methods for the selective and direct manipulation of molecules by creating tools that allow chemists to prepare molecules under particularly mild conditions. The outcomes of the project will include the development of new technology for organic synthesis and forging novel approaches for chemical alkylation and cross-coupling reactions. This can contribute to making important compounds more efficiently, safely and cheaper to produce in the future.Read moreRead less
Organometallic Transformations of Organic Compounds. The program will develop new metal-based catalysts for two main purposes (i) transforming basic hydrocarbons eg. natural gas and low-molecular-weight petroleum products into more advanced compounds (such as alcohols, alkenes and carboxylic acids); and (ii) converting nitrogen gas into nitrogen-containing compounds eg. ammonia or ammonia derivatives. In both projects, the aim is to take readily available and abundant starting materials that ar ....Organometallic Transformations of Organic Compounds. The program will develop new metal-based catalysts for two main purposes (i) transforming basic hydrocarbons eg. natural gas and low-molecular-weight petroleum products into more advanced compounds (such as alcohols, alkenes and carboxylic acids); and (ii) converting nitrogen gas into nitrogen-containing compounds eg. ammonia or ammonia derivatives. In both projects, the aim is to take readily available and abundant starting materials that are currently difficult to utilise and to design and develop specific reagents to convert them to "value-added" products. The program will also explore the mode of action of metal-based reagents leading to better reagent and catalyst design.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100057
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
A diffractometer for small molecule structural elucidation by crystallographic analysis. X-ray diffractometry provides an unambiguous means of identifying the three-dimensional spatial arrangement of atoms within molecules affording important insights into the origins of chemical properties. A modern diffractometer will provide information to help develop new functional materials, therapeutic agents and environmentally sustainable processes.
Advanced cluster materials for optical limiting applications. Materials with significant optical limiting properties are needed for optical device and personnel protection against accidental exposure and hostile threat from high-power lasers. Metal clusters (molecules with several metal atoms) are one of the most promising optical limiting materials known, but while their potential has been highlighted, the systematic studies needed to optimise their performance are lacking. This project will as ....Advanced cluster materials for optical limiting applications. Materials with significant optical limiting properties are needed for optical device and personnel protection against accidental exposure and hostile threat from high-power lasers. Metal clusters (molecules with several metal atoms) are one of the most promising optical limiting materials known, but while their potential has been highlighted, the systematic studies needed to optimise their performance are lacking. This project will assess the optical limiting merit of carefully targeted cluster complexes, and afford structure/property relationships to guide materials development. Read moreRead less
Accessing the therapeutic potential of carbon monoxide. Despite carbon monoxide being regarded as the ”silent killer”, it is now established that this molecule has beneficial effects for a number of conditions and pathologies, including inflammation, organ transplant rejection, bacterial infection, acute liver failure and as an aid in cancer therapies. This project proposes to explore the photochemistry of rhenium-containing species to discover more efficient carbon monoxide delivery agents. By ....Accessing the therapeutic potential of carbon monoxide. Despite carbon monoxide being regarded as the ”silent killer”, it is now established that this molecule has beneficial effects for a number of conditions and pathologies, including inflammation, organ transplant rejection, bacterial infection, acute liver failure and as an aid in cancer therapies. This project proposes to explore the photochemistry of rhenium-containing species to discover more efficient carbon monoxide delivery agents. By combining synthetic chemistry, photochemistry and cellular biology it is anticipated that this multidisciplinary research programme will advance the area of carbon monoxide therapies by preparing safer agents for the targeted and controlled delivery of carbon monoxide.Read moreRead less
Asymmetric Synthesis of Chiral Phosphines, Arsines, and Stibines. There are now chiral phosphine-transition metal catalysts that rival enzymes in their efficiency for the asymmetric synthesis of important chiral drugs, fragrants, cosmetics, nutrients, vitamins, and pesticides. This project is aimed at a generalised asymmetric synthesis of the critical components of these enzyme mimics, notably enantiopure chiral phosphines, but also chiral arsines and stibines, by a highly innovative approach t ....Asymmetric Synthesis of Chiral Phosphines, Arsines, and Stibines. There are now chiral phosphine-transition metal catalysts that rival enzymes in their efficiency for the asymmetric synthesis of important chiral drugs, fragrants, cosmetics, nutrients, vitamins, and pesticides. This project is aimed at a generalised asymmetric synthesis of the critical components of these enzyme mimics, notably enantiopure chiral phosphines, but also chiral arsines and stibines, by a highly innovative approach that involves novel six-electron phosphenium, arsenium, and stibinium cations that are themselves stabilised by chiral phosphines so that chemical breeder reactions are possible. The use of chiral auxiliaries from the natural pool and from biotechnology will also be investigated.Read moreRead less
Organometallic materials for photonics. New high performance materials are required for applications in photonics, an area of increasing importance for Australia's high technology industries. This project addresses two critically important requirements in photonics: materials with enhanced nonlinear optical merit (both quadratic and cubic), needed for applications in optical communications, data storage and computer systems, and materials with significant optical limiting properties, required fo ....Organometallic materials for photonics. New high performance materials are required for applications in photonics, an area of increasing importance for Australia's high technology industries. This project addresses two critically important requirements in photonics: materials with enhanced nonlinear optical merit (both quadratic and cubic), needed for applications in optical communications, data storage and computer systems, and materials with significant optical limiting properties, required for laboratory optical device protection and military applications. Concomitant with these studies, the fundamental organometallic chemistry of alkynylmetal complexes and clusters will be developed, leading into oligomeric, dendritic and polymeric species which are of intrinsic, as well as applied, interest.Read moreRead less
Challenging targets in rare earth metal-organic chemistry. This project aims to prepare highly reactive rare earth organometallic and metal-organic compounds, especially from the free metals, and to determine their structures and reactivity. Abundant rare earth resources position Australia to be a major supplier of these strategic elements. The challenging target systems include coordination stabilised novel ligands, pseudo-Grignard reagents LnR(X) including the rare fluorides, complexes primed ....Challenging targets in rare earth metal-organic chemistry. This project aims to prepare highly reactive rare earth organometallic and metal-organic compounds, especially from the free metals, and to determine their structures and reactivity. Abundant rare earth resources position Australia to be a major supplier of these strategic elements. The challenging target systems include coordination stabilised novel ligands, pseudo-Grignard reagents LnR(X) including the rare fluorides, complexes primed for carbon-fluorine activation, and intermediates from use of lanthanoid reagents in organic synthesis. The project will provide a knowledge base and expertise for the utilisation of Australia's abundant rare earths and will transform the current behaviour of the elements. It builds the expertise and knowledge needed to underpin Australian rare earth processing and develops the breakthrough science needed for new applications in fine chemical manufacturing, catalysis and recycling.Read moreRead less
Earth Abundant Metal Complexes for Nitrogen Activation. This project aims to develop a range of complexes based around earth abundant metals that are capable of activating nitrogen (N2) at ambient pressure and temperature. The project expects to generate new knowledge in the area of organometallic chemistry, specifically with regards to molecular metal-metal bonding and subsequent reactivity towards the activation of nitrogen. The activation of atmospheric nitrogen is performed on a multi-millio ....Earth Abundant Metal Complexes for Nitrogen Activation. This project aims to develop a range of complexes based around earth abundant metals that are capable of activating nitrogen (N2) at ambient pressure and temperature. The project expects to generate new knowledge in the area of organometallic chemistry, specifically with regards to molecular metal-metal bonding and subsequent reactivity towards the activation of nitrogen. The activation of atmospheric nitrogen is performed on a multi-million tonne scale each year and is key to a number of industrial processes. As such, investigations into new and improved catalysts for this process would potentially bring huge financial benefits to industry, as well as benefiting the environment by reducing energy demand and associated climate change.Read moreRead less