Discovery Early Career Researcher Award - Grant ID: DE200100584
Funder
Australian Research Council
Funding Amount
$424,636.00
Summary
DNA Replication Stress: Characterizing ground zero for genomic instability. The overarching goal of this research is to gain insights into key underlying molecular causes of, and responses to, DNA replication stress - one of the most fundamental biological processes enabling life as we know it. I will use advanced interdisciplinary imaging techniques to directly visualize DNA replication stress structures within cells in order to better understand how cells stop this stress from progressing into ....DNA Replication Stress: Characterizing ground zero for genomic instability. The overarching goal of this research is to gain insights into key underlying molecular causes of, and responses to, DNA replication stress - one of the most fundamental biological processes enabling life as we know it. I will use advanced interdisciplinary imaging techniques to directly visualize DNA replication stress structures within cells in order to better understand how cells stop this stress from progressing into DNA damage. Insights into these processes will have the potential to improve preventative and therapeutic approaches to diseases such as cancer and neurodegeneration. Read moreRead less
Micro-dissection of clathrins role in mitosis via chemical biology probes. This project aims to contribute to understanding the molecular mechanisms of the role of a key protein, clathrin, in cell division. In doing so it expects to reveal new approaches to stop uncontrolled cell division and proliferation, the hallmarks of cancer. The outcomes could in the long term inform breakthroughs in cancer treatment, significant enhancements in life quality and a reduction in cancer death rates.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100118
Funder
Australian Research Council
Funding Amount
$370,000.00
Summary
Regional flow cytometry facility. Flow cytometry facility: This project will establish a flow cytometry facility, featuring the latest technology in two separate complementary machines, one an analyser the other a cell sorter. This facility will provide urgently needed replacement of aging infrastructure, and will also provide researchers with new capabilities that will lead to substantial research advances across many diverse fields.
Open framework organic materials for CO2 capture and conversion. The reduction of CO2 emissions from coal-fired power plants is a technological challenge of global significance. This project will address this challenge by developing a unique system, based upon open framework materials, that will selectively capture CO2 from gas streams and then catalyse its transformation into industrially useful chemicals.
Advanced adsorbents for gas separations. Efficient purification of natural gas and separation of similarly-sized molecules in gas mixtures is increasingly important in our drive to develop a more sustainable way of living in an energy-constrained world. This project will develop a new class of adsorbents to deliver a level of separation efficiency much higher than that currently in use.
Data-driven development of photocatalytic and optoelectronic perovskites. This project aims to use materials informatics to discover new, high efficiency perovskites for synthesis and testing in optoelectronic applications. This project expects to identify perovskite composition-property relationships to overcome current drawbacks of high performance perovskites (contain rare or toxic elements and low stability in oxidative and humid environments) by considered selection of elements and their pr ....Data-driven development of photocatalytic and optoelectronic perovskites. This project aims to use materials informatics to discover new, high efficiency perovskites for synthesis and testing in optoelectronic applications. This project expects to identify perovskite composition-property relationships to overcome current drawbacks of high performance perovskites (contain rare or toxic elements and low stability in oxidative and humid environments) by considered selection of elements and their properties. Expected outcomes from this project include new perovskites with commercial potential in critical areas such as energy conversion, photocatalysis and luminescence. This should provide significant benefits including approaches to materials discovery, novel materials and in renewable energy and environmental areas.Read moreRead less
Non-equilibrium material phases. This project aims to synthesise and characterise exotic materials produced in the laboratory under conditions that replicate those inside planets and stars. Highly non-equilibrium processing methods are needed to find entirely new material forms of elements and compounds created under extreme pressure and temperature. The project will use its laser-based synthesis method to explore and understand the non-equilibrium pathways and develop new materials. Understandi ....Non-equilibrium material phases. This project aims to synthesise and characterise exotic materials produced in the laboratory under conditions that replicate those inside planets and stars. Highly non-equilibrium processing methods are needed to find entirely new material forms of elements and compounds created under extreme pressure and temperature. The project will use its laser-based synthesis method to explore and understand the non-equilibrium pathways and develop new materials. Understanding how these materials form could lead to the next materials revolution. This research will lead to materials that industry sectors can exploit for commercial benefits.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100306
Funder
Australian Research Council
Funding Amount
$373,536.00
Summary
Functional Superstructures of Microporous Metal-Organic Frameworks. This project aims to develop metal-organic framework (MOF) superstructures as a new materials platform. MOFs are an emerging class of porous adsorbents that are expected to fulfil a crucial role as functional materials in industrially important applications, including molecular separations and heterogeneous catalysis. However, there is an urgent need for convenient methods to integrate the attractive properties of MOFs with the ....Functional Superstructures of Microporous Metal-Organic Frameworks. This project aims to develop metal-organic framework (MOF) superstructures as a new materials platform. MOFs are an emerging class of porous adsorbents that are expected to fulfil a crucial role as functional materials in industrially important applications, including molecular separations and heterogeneous catalysis. However, there is an urgent need for convenient methods to integrate the attractive properties of MOFs with the unique features of meso- and macrostructured materials, and for a fundamental understanding of the influence of structuring on their material properties. The project intends to synthesise structuralised MOFs as a platform for studies related to their adsorptive and dynamic properties, and to study these systems as next-generation materials for hydrocarbon separations.Read moreRead less
New generation functional materials for 21st century applications: exploiting the properties of naphthalene diimides. This project melds the expertise of several research groups in the area of fluorescent material development. Based on a family of highly fluorescent molecules, the project will focus on designing new sensors, polymeric materials and molecular switching devices.
Light driven degradation of persistent organic pollutants. This project aims to address the accumulation of pollutants in our environment by developing and optimising materials that utilise light energy to breakdown these persistent chemicals. Combining novel techniques and approaches, this project expects to generate new knowledge in the field of materials science and photochemistry. The anticipated outcomes of this project include an advancement of environmental remediation methods and the cap ....Light driven degradation of persistent organic pollutants. This project aims to address the accumulation of pollutants in our environment by developing and optimising materials that utilise light energy to breakdown these persistent chemicals. Combining novel techniques and approaches, this project expects to generate new knowledge in the field of materials science and photochemistry. The anticipated outcomes of this project include an advancement of environmental remediation methods and the capture of pollutants at their source. This should provide significant benefits to both humans and the environment through preventing the adverse impacts of pollutant exposure.Read moreRead less