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
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
Charging transition metals with activating alkanes. The project aims to engineer positively charged metal complexes and use them to explore the chemistry of bound activated alkane ligands. The transformation of cheap, plentiful alkanes into more valuable products is a major quest in chemistry, and complexes of alkanes bound to metals are expected to play a key role in transformations of alkanes. The project intends to use the activated metal bound alkane to transform the normally inert alkane in ....Charging transition metals with activating alkanes. The project aims to engineer positively charged metal complexes and use them to explore the chemistry of bound activated alkane ligands. The transformation of cheap, plentiful alkanes into more valuable products is a major quest in chemistry, and complexes of alkanes bound to metals are expected to play a key role in transformations of alkanes. The project intends to use the activated metal bound alkane to transform the normally inert alkane into compounds with desirable functional groups. This should make the synthesis of alkane complexes stable at room temperature in solution a realistic possibility. These cheap, plentiful alkanes can be turned into more valuable products, bringing benefits to industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100110
Funder
Australian Research Council
Funding Amount
$474,000.00
Summary
High Resolution Mass Spectrometer for Chemical Characterisation in WA. The aim of this proposal is to establish new high resolution mass spectrometry facilities for Western Australia which will support multiple areas of chemical, materials and environmental science. The proposed platform will address a major need for the separation and characterisation of molecules relevant to synthetic and natural products chemistry, advanced materials and environmental analyses. The facility will support a num ....High Resolution Mass Spectrometer for Chemical Characterisation in WA. The aim of this proposal is to establish new high resolution mass spectrometry facilities for Western Australia which will support multiple areas of chemical, materials and environmental science. The proposed platform will address a major need for the separation and characterisation of molecules relevant to synthetic and natural products chemistry, advanced materials and environmental analyses. The facility will support a number of high impact ARC funded research projects in diverse areas, such as plant growth regulation, molecular electronics and environmental contaminants. The new instrumentation will be easy to use, provide advanced high quality data and overall benefit the next generation of researchers in Western Australia.Read moreRead less
Combating Antimicrobial Resistance with Bismuth, Gallium and Indium. This research project focuses on the design, development, and application of new bismuth, gallium and indium compounds as antimicrobial agents. These metals act as iron mimics in vivo and can exert antimicrobial activity while displaying low systemic toxicity in humans. The project aims to exploit this, and the inability of microbes to easily develop resistance towards metals, to combat bacteria for which modern drugs are rapid ....Combating Antimicrobial Resistance with Bismuth, Gallium and Indium. This research project focuses on the design, development, and application of new bismuth, gallium and indium compounds as antimicrobial agents. These metals act as iron mimics in vivo and can exert antimicrobial activity while displaying low systemic toxicity in humans. The project aims to exploit this, and the inability of microbes to easily develop resistance towards metals, to combat bacteria for which modern drugs are rapidly becoming ineffective, as highlighted in the WHO and US Centre for Disease Control list of critical and priority pathogens. The intended outcome is that efficacy will be driven through advances in synthetic and structural chemistry, discovering the mode of action, and creating anti-infective coatings and hydrogels.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
A new molecular platform for catalytic synthesis of heterocycles. This project aims to address the lack of efficient methods to prepare cyclic molecules of biological relevance by utilising novel molecular platforms developed in our laboratories. This project expects to generate new cyclic molecules using these innovative molecular platforms by employing catalysts to reduce raw material and energy cost. The expected outcomes of this project include enhanced chemical technology to prepare cyclic ....A new molecular platform for catalytic synthesis of heterocycles. This project aims to address the lack of efficient methods to prepare cyclic molecules of biological relevance by utilising novel molecular platforms developed in our laboratories. This project expects to generate new cyclic molecules using these innovative molecular platforms by employing catalysts to reduce raw material and energy cost. The expected outcomes of this project include enhanced chemical technology to prepare cyclic molecules of pharmaceutical importance and the training of highly skilled PhD students. This should provide significant benefits, such as increased capacity for the development of new pharmaceuticals and advanced materials.Read moreRead less
Molecular Thermoelectric Materials: A New Hot Topic. This project aims to use the principles of chemistry and molecular electronics to synthesize and study molecules able to directly convert waste heat into electricity through the Seebeck effect. This project expects to generate new knowledge concerning the wire-like properties of molecules and conditions that lead to a high Seebeck coefficient, together with interference effects to suppress thermal conductance. Expected outcomes of this project ....Molecular Thermoelectric Materials: A New Hot Topic. This project aims to use the principles of chemistry and molecular electronics to synthesize and study molecules able to directly convert waste heat into electricity through the Seebeck effect. This project expects to generate new knowledge concerning the wire-like properties of molecules and conditions that lead to a high Seebeck coefficient, together with interference effects to suppress thermal conductance. Expected outcomes of this project include a deeper understanding of chemical structure - molecular electronic property relationships, and enhanced international collaboration with the UK. This should provide benefits in terms of low-cost conversion of waste heat to electrical energy. Read moreRead less
Correlative Imaging of Brain Lipids. This project aims to develop imaging tools and protocols for the detection of lipids in brain tissue and cells. This project expects to generate advanced methodologies to display specific lipid classes and their corresponding structures within tissues and cells, with the ability to be detected and correlated with multiple techniques, which represent a currently unavailable capacity. The expected outcomes of this project are improved opportunities to study lip ....Correlative Imaging of Brain Lipids. This project aims to develop imaging tools and protocols for the detection of lipids in brain tissue and cells. This project expects to generate advanced methodologies to display specific lipid classes and their corresponding structures within tissues and cells, with the ability to be detected and correlated with multiple techniques, which represent a currently unavailable capacity. The expected outcomes of this project are improved opportunities to study lipid biology at the cellular and sub-cellular level across a wide range of in vitro and in vivo models. The outcomes of this project should provide significant knowledge to tackle modern societal challenges in healthy ageing, brain pathologies and neurodegenerative diseases.Read moreRead less
Programmable Organometallics for Spatiotemporal Light Control. This Project aims to develop new materials that control and modify light. The new organometallics from this Project are anticipated to display world record light intensity-dependent absorption and other phenomena. These new programmable molecules are expected to respond to environmental stimuli with precise spatial control. Anticipated outcomes of this Project include environmental sensors and a technology platform for targeted medic ....Programmable Organometallics for Spatiotemporal Light Control. This Project aims to develop new materials that control and modify light. The new organometallics from this Project are anticipated to display world record light intensity-dependent absorption and other phenomena. These new programmable molecules are expected to respond to environmental stimuli with precise spatial control. Anticipated outcomes of this Project include environmental sensors and a technology platform for targeted medical imaging and light-responsive therapies. This Project should provide significant benefits including possible commercialisation of the new materials, enhanced research capacity, training students and a postdoctoral fellow with unique skills, and the strengthening of research linkages with strategic partners.Read moreRead less