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Towards Nano-circuits: 2 and 3-Dimensional Carbon-Wired Nano-architectures. Whilst Australia has a world-class profile in organotransition metal chemistry, main-group chemistry is under-represented, despite the enormous technological importance of materials based on these elements. In addition to the fundamental breakthrough science to be explored, the project will provide a training vehicle for 5 young scientists in both main group and organometallic chemistry. The target compounds involve an e ....Towards Nano-circuits: 2 and 3-Dimensional Carbon-Wired Nano-architectures. Whilst Australia has a world-class profile in organotransition metal chemistry, main-group chemistry is under-represented, despite the enormous technological importance of materials based on these elements. In addition to the fundamental breakthrough science to be explored, the project will provide a training vehicle for 5 young scientists in both main group and organometallic chemistry. The target compounds involve an essentially unique marriage of the fields of main-group and transition metal chemistry to provide complex nano-architectures based on the modular interconnection of metals and non-metals by carbon wires at the molecular level - nanoscopic counterparts of macroscopic circuit components.Read moreRead less
Understanding and Harnessing the Unique and Curious Metal Boron Bond: Unlocking the Metallaboratrane Cage. Metal-boron bonding holds enormous technological importance due to the emergence of boron-based metal-mediated synthetic transformations that access a diversity of high value-added fine chemicals. Whilst Australia boasts an emergent boron-based fine chemicals industry, no research program into the nature of metal boron bonding exists to provide either fundamental science or advanced trainin ....Understanding and Harnessing the Unique and Curious Metal Boron Bond: Unlocking the Metallaboratrane Cage. Metal-boron bonding holds enormous technological importance due to the emergence of boron-based metal-mediated synthetic transformations that access a diversity of high value-added fine chemicals. Whilst Australia boasts an emergent boron-based fine chemicals industry, no research program into the nature of metal boron bonding exists to provide either fundamental science or advanced training in organometallic boron chemistry. The proposed work offers two distinct national benefits: The maintenance of a discipline in which Australia leads the world (metallaboratranes) and the genesis of one, which whilst intensely studied elsewhere, is notably absent from the Australian science base (low coordinate, unsaturated boron chemistry).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
Borametallacycles: confluence of metallacycle and boracycle chemistries. Metallacycles are cyclic structures constructed from a transition metal and the first row elements, such as carbon, nitrogen and oxygen. They underpin numerous technological applications in catalysis and materials chemistry. Borametallacycles which include the missing element boron will be explored with a view to developing new materials with novel properties.
One coordinate carbon and boron: Universal progenitor ligands. Compounds with bonds between metals and carbon (organometallic chemistry) underpin innumerable important industrial processes from fine chemicals to bulk agrochemical and polymer synthesis. Yet the simplest example, a single atom of carbon bound to a metal has only recently been discovered and is poorly understood. Australia's fledgling boron fine chemicals industry similarly benefits from metal-based processes. However, compounds wi ....One coordinate carbon and boron: Universal progenitor ligands. Compounds with bonds between metals and carbon (organometallic chemistry) underpin innumerable important industrial processes from fine chemicals to bulk agrochemical and polymer synthesis. Yet the simplest example, a single atom of carbon bound to a metal has only recently been discovered and is poorly understood. Australia's fledgling boron fine chemicals industry similarly benefits from metal-based processes. However, compounds with a single boron atom bound to a metal remain unknown. This proposal addresses metal-carbon and metal-boron chemistry from the most basic perspective, that of a single atom of boron or carbon, including the development of novel synthetic approaches and skills for the characterisation of such curious species.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100524
Funder
Australian Research Council
Funding Amount
$422,574.00
Summary
Heterometallic iron-molybdenum complexes for nitrogen activation. This project aims to develop a range of bio-inspired, mixed metal iron-molybdenum complexes that are capable of activating molecular nitrogen, N2, at ambient pressure and temperature. The activation of atmospheric N2 is performed on a multi-million tonne scale each year and is key to a number of industrial processes. The project expects to generate new knowledge in the area of organometallic chemistry, specifically with regards to ....Heterometallic iron-molybdenum complexes for nitrogen activation. This project aims to develop a range of bio-inspired, mixed metal iron-molybdenum complexes that are capable of activating molecular nitrogen, N2, at ambient pressure and temperature. The activation of atmospheric N2 is performed on a multi-million tonne scale each year and is key to a number of industrial processes. 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 N2. Expected outcomes include new and improved catalysts, which will provide significant financial benefits to industry, as well as benefiting the environment by reducing energy demand.Read moreRead less
Boryl Pincers and Beyond: Taming Borometallic Chemistry. Industrial applications of coordination complexes in catalysis reduce energy input and environmental impact but almost exclusively involve classical donors such as nitrogen, oxygen, sulfur and phosphorus. Boron, whilst prevalent and environmentally benign, is under-utilised in such applications, in part due to the high reactivity of the metal boron bond.
This research will seek to tame and then exploit the unique features of boron within p ....Boryl Pincers and Beyond: Taming Borometallic Chemistry. Industrial applications of coordination complexes in catalysis reduce energy input and environmental impact but almost exclusively involve classical donors such as nitrogen, oxygen, sulfur and phosphorus. Boron, whilst prevalent and environmentally benign, is under-utilised in such applications, in part due to the high reactivity of the metal boron bond.
This research will seek to tame and then exploit the unique features of boron within pincer ligand frameworks in metal coordination complexes, with particular attention focusing on, but not limited to catalytic alkyne metathesis.Read moreRead less
Bimetallic carbidos: hard-wiring a single atom of carbon. This project aims to explore the design, synthesis, characterisation and applications of novel materials in which metals are bridged by a single carbon atom. Materials based on metals (M) separated by a single oxygen atom (O) underpin all manner of technologies from the pigments of antiquity to modern electronics. Electronic/magnetic communication across MOM bridges is thus extremely well understood. Materials with two metals bridged by o ....Bimetallic carbidos: hard-wiring a single atom of carbon. This project aims to explore the design, synthesis, characterisation and applications of novel materials in which metals are bridged by a single carbon atom. Materials based on metals (M) separated by a single oxygen atom (O) underpin all manner of technologies from the pigments of antiquity to modern electronics. Electronic/magnetic communication across MOM bridges is thus extremely well understood. Materials with two metals bridged by one carbon atom (MCM) are in contrast, rare and poorly understood. Developing synthetic routes to such materials will make it possible to map the diversity of chemical and electronic features against theoretical models in search of new materials with unique reactivities and properties for commercial exploitation.Read moreRead less
Heteroatomic organometallic molecular wires. This project aims to design strategies for the modular construction of heteroatomic molecular wires. Molecular wires are the smallest possible component for miniaturisation of electronic circuitry: metal atoms joined by a linear conducting chain of carbon atoms. This project addresses the synthetic challenge of designing strategies for the modular construction of unprecedented heteroatomic molecular wires. Unique electro-optical properties may be deve ....Heteroatomic organometallic molecular wires. This project aims to design strategies for the modular construction of heteroatomic molecular wires. Molecular wires are the smallest possible component for miniaturisation of electronic circuitry: metal atoms joined by a linear conducting chain of carbon atoms. This project addresses the synthetic challenge of designing strategies for the modular construction of unprecedented heteroatomic molecular wires. Unique electro-optical properties may be developed (for switching, sensing, data storage applications) for subsequent applications in molecular electronics industries. Electro-optical properties could be used in molecular electronics industries.Read moreRead less
Boron and silicon based pincer ligands for environmentally responsible catalysis. The production of everyday chemicals (pharmaceuticals, agrochemicals, polymers) comes at a price, economic and environmental. Metal catalysts significantly reduce the environmental impact of both the associated energy requirements and waste products. New classes of catalysts will be developed based on the unconventional elements boron and silicon.