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
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.
Polyanionic carbon ligands in metal complexes as new reagents in organometallic and inorganic chemistry. The proposed research will benefit Australia by creating a knowledge base in an internationally important area of chemistry. It addresses fundamental questions in organometallic chemistry that will be of great significance for chemical synthesis as well as for a greater understanding of structure and bonding. Through an integrated and interdisciplinary approach, the exploitation of technologi ....Polyanionic carbon ligands in metal complexes as new reagents in organometallic and inorganic chemistry. The proposed research will benefit Australia by creating a knowledge base in an internationally important area of chemistry. It addresses fundamental questions in organometallic chemistry that will be of great significance for chemical synthesis as well as for a greater understanding of structure and bonding. Through an integrated and interdisciplinary approach, the exploitation of technologies arising from this research programme will be explored. In addition to the academic community, these technologies will benefit hi-tech industries including pharmaceutical and fine chemical concerns which will gain from the use of polymetalated carbon species in organic and inorganic synthesis, catalysis and the development of new materials.Read moreRead less
Synthesis, Synergy and Sustainability: Development of active-metal reagents. The design and realisation of new and important molecules requires innovative and efficient methods. This project will create a new store of active-metal molecular tools for the selective, catalytic and atom efficient construction of a diverse library of phosphorus heterocyclic scaffolds and chemical feedstocks relevant to biological, medicinal, and materials chemistry, and the fine chemical industry. Parallel studies e ....Synthesis, Synergy and Sustainability: Development of active-metal reagents. The design and realisation of new and important molecules requires innovative and efficient methods. This project will create a new store of active-metal molecular tools for the selective, catalytic and atom efficient construction of a diverse library of phosphorus heterocyclic scaffolds and chemical feedstocks relevant to biological, medicinal, and materials chemistry, and the fine chemical industry. Parallel studies employing environmentally friendly and benign deep eutectic solvents will allow for replacement of traditional hazardous volatile organic solvents, putting the newly created active-metal reagents at the forefront of the necessary shift towards a more sustainable and 'green' polar organometallic chemistry. Read moreRead less
Low oxidation state magnesium complexes: multitalented reagents for sustainable chemical synthesis. The chemistry of stable low oxidation state s-block compounds was initiated at Monash in 2007. In addition to being of major fundamental importance, applications of these highly reactive systems have rapidly developed. To cement Australia's international lead in this emerging and competitive field, this project aims to develop a new generation of magnesium(I) (and related) compounds, and to instal ....Low oxidation state magnesium complexes: multitalented reagents for sustainable chemical synthesis. The chemistry of stable low oxidation state s-block compounds was initiated at Monash in 2007. In addition to being of major fundamental importance, applications of these highly reactive systems have rapidly developed. To cement Australia's international lead in this emerging and competitive field, this project aims to develop a new generation of magnesium(I) (and related) compounds, and to install them as sought after reagents for sustainable synthetic methodologies. For the first time, environmentally benign s-block compounds will be utilised for the low energy stoichiometric and catalytic transformation of abundant, often inert gaseous small molecules, for example, hydrogen, nitrogen, carbon dioxide, carbon monoxide, to value added products important to industry and academia.Read moreRead less
Advancing the Metal-Organic Chemistry of the Heavy Alkaline Earth Elements. The project will open up a new area in Australian metal based chemical research, deriving high value added products from the already existing exploitation of Australia's substantial alkaline earth metal mineral resources. Internationally recognised expertise in the design and manipulation of highly reactive chemical tools will contribute breakthrough science and innovation to the growing pharmaceutical, fine chemicals an ....Advancing the Metal-Organic Chemistry of the Heavy Alkaline Earth Elements. The project will open up a new area in Australian metal based chemical research, deriving high value added products from the already existing exploitation of Australia's substantial alkaline earth metal mineral resources. Internationally recognised expertise in the design and manipulation of highly reactive chemical tools will contribute breakthrough science and innovation to the growing pharmaceutical, fine chemicals and smart materials industry, with the potential to provide nascent and established Australian companies a competitive edge in new product development. Students will be trained in the necessary skills to succeed in and expand such technically demanding area of metal based chemistry.Read moreRead less
Frontiers in synthetic and structural rare earth chemistry. Rare earth elements are a major under-utilised Auatralian resource.
Their commercial development requires knowledge and progression of their
chemistry. Advancing the chemistry of highly reactive, air-sensitive
metalorganics will provide the breakthrough science to underpin future
applications in chemical manufacture, catalysis and new materials.
Transformation of rare earth chemistry to achieve behaviour hitherto
atypical of these ....Frontiers in synthetic and structural rare earth chemistry. Rare earth elements are a major under-utilised Auatralian resource.
Their commercial development requires knowledge and progression of their
chemistry. Advancing the chemistry of highly reactive, air-sensitive
metalorganics will provide the breakthrough science to underpin future
applications in chemical manufacture, catalysis and new materials.
Transformation of rare earth chemistry to achieve behaviour hitherto
atypical of these elements by steric and electronic modulation of
attached groups will value-add to their properties.Read moreRead less
Rare Earth Metal-Organic Compounds - A Source of Continuing Excitement. Australia has the world's second largest rare earth resources which are at best exported unprocessed leading to an 80-fold mark up on import of separated products. This project builds the expertise and knowledge needed to underpin Australian rare earth processing and develops the breakthrough science needed for new applications or rare earths.