Functionalised nanomaterials for application as multimodal cancer imaging agents. Nanomaterials offer exciting opportunities for emerging diagnostic applications targeted to specific diseases. In this project, cutting-edge fundamental scientific developments will be pursued that will advance the application of nanomaterials in the diagnosis of cancer, a disease that accounts for over 40,000 deaths in Australia annually.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100109
Funder
Australian Research Council
Funding Amount
$530,000.00
Summary
Small molecule X-ray molecular structure elucidation facility. X-ray diffraction plays a key role in identification and molecular characterisation. X-ray techniques are the single most widely used analytical resource in structure determination and provide invaluable information for scientists working in the fields of synthesis, nanotechnology, polymer chemistry, and protein chemistry, amongst many others. The facility brings together a multidisciplinary team of scientists and provides state-of-t ....Small molecule X-ray molecular structure elucidation facility. X-ray diffraction plays a key role in identification and molecular characterisation. X-ray techniques are the single most widely used analytical resource in structure determination and provide invaluable information for scientists working in the fields of synthesis, nanotechnology, polymer chemistry, and protein chemistry, amongst many others. The facility brings together a multidisciplinary team of scientists and provides state-of-the-art research and training facilities for these techniques.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100186
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Base stabilised dicarbon as a new building block for supramolecular organometallic chemistry. Diamond, coal and graphite are the forms of carbon ("allotropes") found in everyday life. The discovery of two further allotropes of carbon, the fullerenes and graphene both led to Nobel Prize awards. We have identified a method to stabilize another form of carbon, dicarbon, and will harness its properties for the formation of new materials.
C-H to C-F using electrochemistry and gold catalysis. Gold offers great potential in chemical catalysis and this project will use a fascinating new class of gold compounds discovered by the CIs, to develop novel catalysts. Using this chemistry a series of gold(III) compounds with fluoride ligands will be prepared. The catalytic properties of these molecules will then be explored, with a particular focus on adding value to arene hydrocarbons. The ultimate goal of the project is development of new ....C-H to C-F using electrochemistry and gold catalysis. Gold offers great potential in chemical catalysis and this project will use a fascinating new class of gold compounds discovered by the CIs, to develop novel catalysts. Using this chemistry a series of gold(III) compounds with fluoride ligands will be prepared. The catalytic properties of these molecules will then be explored, with a particular focus on adding value to arene hydrocarbons. The ultimate goal of the project is development of new catalysts for the formation of carbon-fluorine bonds and the selective fluorination of organic
compounds. Fluorinated organic molecules are of critical importance in medicinal chemistry and new catalysts of this type offers the potential for better synthesis of medicines and diagnostic agents.Read moreRead less
Functional supramolecular materials for sensing and sequestration. This project will construct materials by controlling the assembly of molecules by virtue of the weak forces between them and the manner in which they assemble will be assessed. These materials will be capable of storing, sensing or separating small molecules with biological or environmental relevance or common gases.
Discovery Early Career Researcher Award - Grant ID: DE130100615
Funder
Australian Research Council
Funding Amount
$374,607.00
Summary
Rational design and fabrication of polyoxometalate based nanodevices. Currently switches, memories and sensors are constructed through physical manipulation of their various components. Using single molecules we plan to develop self-organising systems, resulting in self-constructing devices. This will enable device miniaturisation to the smallest of length scales, dramatically influencing modern day electronics.
Molecular Group 2 Metal(I) complexes: from chemical landmarks to versatile reagents. This project aims to systematically expand an internationally acclaimed pilot study which led to the initiation of a completely new and breakthrough field of chemistry, namely that of Group 2 metal-metal bonded complexes. The high reactivity of these systems will lead to them finding wide ranging applications in synthesis and materials chemistry.
The systematic development of fundamentally important group 15 compounds: their applications to innovative industrial and environmental processes. The strong coordinating ability of organo-phosphorus/arsonic acids will be harnessed to support a series of metallic clusters that will be exploited for their use as magnetic materials in gas storage and as catalysts. The novel acids will be investigated for use as water soluble purification agents for, for example, mercury, uranium and lead.
Luminophores and photochromes: towards molecular componentry. This project aims to enhance current knowledge of luminogenic and photochromic molecules, including self-assembled structures, and materials composed thereof, by constructing a computationally guided compound library. Translation of primary outcomes towards utility in emerging technologies including passive light harvesting from transparent surfaces, bio-sensors and photo-responsive devices will be pursued in collaboration with both a ....Luminophores and photochromes: towards molecular componentry. This project aims to enhance current knowledge of luminogenic and photochromic molecules, including self-assembled structures, and materials composed thereof, by constructing a computationally guided compound library. Translation of primary outcomes towards utility in emerging technologies including passive light harvesting from transparent surfaces, bio-sensors and photo-responsive devices will be pursued in collaboration with both academia and industry. The expected outcomes from this project include the creation of opportunities to explore the manufacture and commercialisation of high-value products with Australian industry. This will provide significant benefits, such as reduction in the carbon footprint of homes, businesses and other applicable structures due to passive power generation, while creating jobs and up-skilling the workforce.Read moreRead less