Reactivity Enhanced Low-Valent Alkaline Earth Metal Compounds. The project aims to develop highly activated low oxidation state alkaline earth metal complexes as cheap and sustainable alternatives to toxic/expensive late transition metal complexes, that currently dominate the transformation of inert small molecule substrates into value-added organic chemicals. The project expects to generate major fundamental and applied advances in chemistry, using innovative synthetic and computational approac ....Reactivity Enhanced Low-Valent Alkaline Earth Metal Compounds. The project aims to develop highly activated low oxidation state alkaline earth metal complexes as cheap and sustainable alternatives to toxic/expensive late transition metal complexes, that currently dominate the transformation of inert small molecule substrates into value-added organic chemicals. The project expects to generate major fundamental and applied advances in chemistry, using innovative synthetic and computational approaches, and a multidisciplinary collaborative team. Expected outcomes include building of academic and, later, industrial research capacity, knowledge, an international network, and a highly trained workforce. Success should see substantial economic, environmental and societal benefits flowing to Australia.Read moreRead less
Teaching Main Group Compounds to Activate Catalytically Relevant Bonds. The project aims to generate novel, earth abundant main group compounds, with the ultimate objective of developing these as sustainable replacements for toxic/expensive late transition metal complexes, that are currently central to numerous stoichiometric and catalytic synthetic transformations. The project expects to generate major fundamental and applied advances in chemistry, using innovative synthetic and computational a ....Teaching Main Group Compounds to Activate Catalytically Relevant Bonds. The project aims to generate novel, earth abundant main group compounds, with the ultimate objective of developing these as sustainable replacements for toxic/expensive late transition metal complexes, that are currently central to numerous stoichiometric and catalytic synthetic transformations. The project expects to generate major fundamental and applied advances in chemistry, using innovative synthetic and computational approaches, and a multidisciplinary collaborative team. Expected outcomes include building of academic and, later, industrial research capacity, knowledge, an international research network, and a highly trained workforce. Success should see substantial economic, environmental and societal benefits flowing to Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100068
Funder
Australian Research Council
Funding Amount
$417,237.00
Summary
Original metal-based catalysts for enzyme-inspired CO2 activation. The chemical utilisation of CO2 is one of two major strategies in achieving net negative CO2 emissions mitigating the environmental and socioeconomic damage of global warming. Inspired by the ability of natural enzymes to efficiently utilise molecules like CO2, this project aims to develop original metal-based catalysts as enzyme mimics for the efficient transformation of CO2. It will deliver practical strategies to transform CO2 ....Original metal-based catalysts for enzyme-inspired CO2 activation. The chemical utilisation of CO2 is one of two major strategies in achieving net negative CO2 emissions mitigating the environmental and socioeconomic damage of global warming. Inspired by the ability of natural enzymes to efficiently utilise molecules like CO2, this project aims to develop original metal-based catalysts as enzyme mimics for the efficient transformation of CO2. It will deliver practical strategies to transform CO2 into value-added materials permanently removing it from the atmosphere. Project outcomes are expected to enhance industry’s capacity to use CO2 as a feedstock chemical for the production of fuels and materials, providing significant economic and environmental benefits through CO2 upcycling and recycling.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC230100046
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Training Centre for Radiochemical Technologies and Precision Radiopharmaceuticals. This project aims to train the next generation of radiochemists and discover new molecular approaches to harness radioactivity. Novel chemistry exploiting molecular incorporation of radioactive elements, stable chelation of metal radionuclides, bioconjugation methodologies, radioactivity capture via nanomaterials and cages, and the design of new peptidomimetic targeting molecules will deliver technological adv ....ARC Training Centre for Radiochemical Technologies and Precision Radiopharmaceuticals. This project aims to train the next generation of radiochemists and discover new molecular approaches to harness radioactivity. Novel chemistry exploiting molecular incorporation of radioactive elements, stable chelation of metal radionuclides, bioconjugation methodologies, radioactivity capture via nanomaterials and cages, and the design of new peptidomimetic targeting molecules will deliver technological advances to radiopharmaceutical science. Outcomes will include a highly-skilled workforce and enhanced commercial capacity to meet a rapidly escalating global radiopharmaceutical market. This project will provide significant benefits by securing an internal supply chain and know-how for cutting-edge radiochemical technologies.Read moreRead less
Magnesium(I) complexes: Potent workhorse reagents. This project aims to install magnesium(I) compounds as powerful and selective reagents to prepare metal-metal bonded compound classes that are otherwise inaccessible. These environmentally benign species will be viable alternatives to established systems, incorporating expensive and toxic metals, which are currently used for the stoichiometric/catalytic transformation of small molecules to value added products. The project is expected to cement ....Magnesium(I) complexes: Potent workhorse reagents. This project aims to install magnesium(I) compounds as powerful and selective reagents to prepare metal-metal bonded compound classes that are otherwise inaccessible. These environmentally benign species will be viable alternatives to established systems, incorporating expensive and toxic metals, which are currently used for the stoichiometric/catalytic transformation of small molecules to value added products. The project is expected to cement Australia's internationally leading role in the emerging field of low oxidation state s-block chemistry. The development and commercialisation of magnesium(I), and related compounds as reagents for the selective synthesis of value added products will provide significant economic benefits to fine chemicals industries.Read moreRead less
Low-Valent p-Block Compounds: Taking on Noble Roles in Catalysis. In this project, innovative approaches will be employed to access new, and fundamentally important, classes of low oxidation state main group compounds, the electronic properties and reactivity of which will be readily tuned to mimic those of noble transition metal complexes. The project aims to harness these attributes, for the first time, to establish such compounds as cheap and sustainable alternatives to the expensive and toxi ....Low-Valent p-Block Compounds: Taking on Noble Roles in Catalysis. In this project, innovative approaches will be employed to access new, and fundamentally important, classes of low oxidation state main group compounds, the electronic properties and reactivity of which will be readily tuned to mimic those of noble transition metal complexes. The project aims to harness these attributes, for the first time, to establish such compounds as cheap and sustainable alternatives to the expensive and toxic transition metal catalysts that are currently essential to numerous synthetic processes utilised in academia and industry. The involvement of a synergistic international network of collaborators will be central to the success of this project, which offers major academic, environmental and economic benefits to Australia.Read moreRead less
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: 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
Emergent properties in spin crossover materials. This project aims to develop ‘intelligent’ materials in which emergent properties arise due to the strategic combination of spin switching with other functionalities. Spin crossover is a versatile form of molecular switch which can reversibly change structure, colour and magnetism using convenient external stimuli. In probing new and interesting forms of interplay between technologically relevant properties, this work addresses the science of host ....Emergent properties in spin crossover materials. This project aims to develop ‘intelligent’ materials in which emergent properties arise due to the strategic combination of spin switching with other functionalities. Spin crossover is a versatile form of molecular switch which can reversibly change structure, colour and magnetism using convenient external stimuli. In probing new and interesting forms of interplay between technologically relevant properties, this work addresses the science of host-guest and electronic/magnetic systems and could lead to materials worthy of commercial development to underpin a range of future high-level technologies spanning low energy separations, molecular sensing, data storage, and electronic/magnetic/optical device componentry.Read moreRead less
Multifunctional hybrid spin crossover materials. Spin-crossover is a fascinating class of molecular switching transition for which pronounced changes in molecular structure, colour and magnetism can be induced reversibly through variation of temperature, pressure, light irradiation, magnetic field and chemical environment. This project targets the strategic development of new spin-crossover systems where cooperativity between switching centres will lead to advanced molecules and materials having ....Multifunctional hybrid spin crossover materials. Spin-crossover is a fascinating class of molecular switching transition for which pronounced changes in molecular structure, colour and magnetism can be induced reversibly through variation of temperature, pressure, light irradiation, magnetic field and chemical environment. This project targets the strategic development of new spin-crossover systems where cooperativity between switching centres will lead to advanced molecules and materials having unprecedented host-guest capabilities, magnetic ordering, memory retention and a range of exotic multifunctional properties. The work addresses several fundamental questions in the science of electronic systems and will lead to advanced switchable materials worthy of commercial development.Read moreRead less