Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347662
Funder
Australian Research Council
Funding Amount
$195,000.00
Summary
Laser Ablation System for Elemental Analysis and Tropical Environmental Research. This application seeks funding for a Laser Ablation system as a sample introduction system for the current Inductively Coupled Plasma Mass Spectrometer (LA-ICPMS). The proposed LA-ICPMS facility will provide a trace element analytical facility that will be used for research in northern Australia which will enhance and develop strong and sustainable collaborative partnerships in the areas of conservation biology, ....Laser Ablation System for Elemental Analysis and Tropical Environmental Research. This application seeks funding for a Laser Ablation system as a sample introduction system for the current Inductively Coupled Plasma Mass Spectrometer (LA-ICPMS). The proposed LA-ICPMS facility will provide a trace element analytical facility that will be used for research in northern Australia which will enhance and develop strong and sustainable collaborative partnerships in the areas of conservation biology, living resource management, tropical environmental science and resource development. The facility will not be simply providing a routine analytical service. It will be used to develop innovative approaches to environmental management and sustainable development and ensure a continued high level of research and research training which will contribute to regional development.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560725
Funder
Australian Research Council
Funding Amount
$127,042.00
Summary
Enhancing the Monash-VIEPS Stable Isotope Facility. This proposal is to enhance the Monash-Victorian Institute of Earth and Planetary Sciences (VIEPS) Stable Isotope Facility to expand our capacity for state-of-the-art research in hydrogeology, hydrology, aqueous chemistry, modern and palaeoclimatology, sedimentology, geochemistry, economic geology, and biological sciences. This facility will then have an analytical capability that is at least the equal of those elsewhere in Australia and which ....Enhancing the Monash-VIEPS Stable Isotope Facility. This proposal is to enhance the Monash-Victorian Institute of Earth and Planetary Sciences (VIEPS) Stable Isotope Facility to expand our capacity for state-of-the-art research in hydrogeology, hydrology, aqueous chemistry, modern and palaeoclimatology, sedimentology, geochemistry, economic geology, and biological sciences. This facility will then have an analytical capability that is at least the equal of those elsewhere in Australia and which will maintain our position as a World Class stable isotope research facility. The enhanced facility will permit new research to be carried out that will lead to new collaborations both within the traditional Earth Sciences and across disciplines.Read moreRead less
Early Archaean Ecology - Exploring the Evidence and Habitats for Early (3.6-3.85 billion year old) Life. The prime scientific quest of the 21st century will be the origin of life. The earliest evidence for life is at 3.85 Ga (billion-years) in the world's oldest-known sediments from Akilia, Greenland. These rocks were contorted and heated during later crustal upheavals, and the evidence for life at 3.85 Ga is controversial. Such life would be highly significant, because then first, primitive li ....Early Archaean Ecology - Exploring the Evidence and Habitats for Early (3.6-3.85 billion year old) Life. The prime scientific quest of the 21st century will be the origin of life. The earliest evidence for life is at 3.85 Ga (billion-years) in the world's oldest-known sediments from Akilia, Greenland. These rocks were contorted and heated during later crustal upheavals, and the evidence for life at 3.85 Ga is controversial. Such life would be highly significant, because then first, primitive life arose before the known stratigraphic record. The project will extend the methods used to detect earliest life, and use Greenland rocks to explore other possible early habitats (submarine volcanic rocks and hot springs) and understand its environment.Read moreRead less
The geomicrobiology and (bio)geochemistry of platinum, palladium and rhodium. Few economic (Platinum) Pt, (Palladium) Pd or (Rhodium) Rh deposits are known in Australia despite an abundance of potential host rock. By improving onshore exploration techniques this project will ensure the supply of these strategic metals to the Australian economy. By integrating geochemical, molecular microbial and microanalyses (e.g., synchrotron) techniques this project will also: (i) enhance Australia's status i ....The geomicrobiology and (bio)geochemistry of platinum, palladium and rhodium. Few economic (Platinum) Pt, (Palladium) Pd or (Rhodium) Rh deposits are known in Australia despite an abundance of potential host rock. By improving onshore exploration techniques this project will ensure the supply of these strategic metals to the Australian economy. By integrating geochemical, molecular microbial and microanalyses (e.g., synchrotron) techniques this project will also: (i) enhance Australia's status in the breakthrough science of Geomicrobiology; (ii) secure a leading role for Australian science in the assessment of anthropogenic Pt, Pd and Rh pollution; (iii) access expertise developed overseas by fostering international collaborations; and (iv) explore the transformational capabilities of microbiota for ore-processing of and nano-particle production.Read moreRead less
Molecular fossils, environmental genomics and the natural history of an Australian salt lake. Increasing salinity of lakes is a critical problem for sustainable water supply in Australia. To comprehend the consequences of human-induced salinization, it is crucial to understand salt lakes at their most fundamental level. This project develops pioneering technologies to elucidate the microbial ecology and geochemistry of salt lakes in unprecedented detail. It will open new pathways to unravel how ....Molecular fossils, environmental genomics and the natural history of an Australian salt lake. Increasing salinity of lakes is a critical problem for sustainable water supply in Australia. To comprehend the consequences of human-induced salinization, it is crucial to understand salt lakes at their most fundamental level. This project develops pioneering technologies to elucidate the microbial ecology and geochemistry of salt lakes in unprecedented detail. It will open new pathways to unravel how microbial ecosystems adapt to increasing salinization, and how they reacted to climate fluctuations in the past. Students will gain multidisciplinary skills in environmental genomics, proteomics and geochemistry, a unique combination that will become decisive for understanding and preserving ecosystems on our continent.Read moreRead less
Chemistry of the Transport of Nutrient Copper in Biological Cells. Nutrient trace metals such as copper are needed for enzymes by living organisms but are toxic in excess. Defects in copper metabolism cause Menkes and Wilson diseases in humans and there are direct connections to neurodegenerative diseases (eg, Alzheimer, Parkinson, Creutzfeldt-Jakob, motor neuron diseases). It is crucial to understand how healthy cells control toxic but essential copper so that enlightened intervention is possib ....Chemistry of the Transport of Nutrient Copper in Biological Cells. Nutrient trace metals such as copper are needed for enzymes by living organisms but are toxic in excess. Defects in copper metabolism cause Menkes and Wilson diseases in humans and there are direct connections to neurodegenerative diseases (eg, Alzheimer, Parkinson, Creutzfeldt-Jakob, motor neuron diseases). It is crucial to understand how healthy cells control toxic but essential copper so that enlightened intervention is possible when disturbances of copper metabolism become pathological. The chemistry of key molecules will be studied to reveal their essential properties and thereby to understand the molecular basis of the copper-linked diseases.Read moreRead less
Molecular Characterisation of Metal Transport Proteins. The trace metals are essential to life. The secrets of their catalytic and structural roles are under intensive scrutiny. The molecular mechanisms which regulate concentrations of nutrient metals in biological cells remain poorly understood. Errors in metal metabolism cause disease. For example, defects in copper metabolism cause Menkes and Wilson diseases in humans and there are connections of copper and zinc to neuro-degenerative disea ....Molecular Characterisation of Metal Transport Proteins. The trace metals are essential to life. The secrets of their catalytic and structural roles are under intensive scrutiny. The molecular mechanisms which regulate concentrations of nutrient metals in biological cells remain poorly understood. Errors in metal metabolism cause disease. For example, defects in copper metabolism cause Menkes and Wilson diseases in humans and there are connections of copper and zinc to neuro-degenerative diseases such as Alzheimer and Creutzfeldt-Jakob (mad cow). This project will study the chemistry of metabolic pathways responsible for import of nutrient copper and other metals into biological cells.Read moreRead less
Tuneable monodispersed nanoparticles and nanoparticle superstructures. Integrating spinning disc processing (SDP), which is new to Australia, with advances in magnetic properties of nanoparticles will have wide ranging applications in nanotechnology. The cutting edge research will foster collaboration with industry, and lead to new industries in memory device technology, nano-medicine, and catalysis, through exploiting commercial opportunities. Continuous flow SDP technology in industry has a s ....Tuneable monodispersed nanoparticles and nanoparticle superstructures. Integrating spinning disc processing (SDP), which is new to Australia, with advances in magnetic properties of nanoparticles will have wide ranging applications in nanotechnology. The cutting edge research will foster collaboration with industry, and lead to new industries in memory device technology, nano-medicine, and catalysis, through exploiting commercial opportunities. Continuous flow SDP technology in industry has a small footprint and low capital cost outlay. The project will provide excellent research training in a range of scientific skills and in professional development, and will involve overseas PhD exchange programs. The exciting research incorporating nano-toxicology will enhance public opinion towards nanotechnology.Read moreRead less
Electrochemically Driven Molybdoenzyme Catalysis. Enzymes that catalyse oxidation and reduction reactions need to exchange electrons with their substrate and this supply of electrons needs to be sustained. Artificially reconstituted systems can be developed where the enzyme is coupled with an electrode and the current (electrons) exchanged during the reaction are measured directly. In this project we will reveal whether some unusual and unexplained electrochemical phenomena seen before are relat ....Electrochemically Driven Molybdoenzyme Catalysis. Enzymes that catalyse oxidation and reduction reactions need to exchange electrons with their substrate and this supply of electrons needs to be sustained. Artificially reconstituted systems can be developed where the enzyme is coupled with an electrode and the current (electrons) exchanged during the reaction are measured directly. In this project we will reveal whether some unusual and unexplained electrochemical phenomena seen before are related to the properties of the enzymes themselves or the ways in which their experiments have been conducted.Read moreRead less
Understanding aerobic respiration: Models for the catalytic centre in proton-pumping heme-copper oxidases. This project tackles ?head on? a key challenge in contemporary biological inorganic chemistry, understanding how at the atomic level aerobic life uses oxygen. All life we see is aerobic, and thus the conceptual advances from this research will progress understanding of our world and ourselves? an important cultural goal. Advancing knowledge of such fundamental processes sits firmly in the a ....Understanding aerobic respiration: Models for the catalytic centre in proton-pumping heme-copper oxidases. This project tackles ?head on? a key challenge in contemporary biological inorganic chemistry, understanding how at the atomic level aerobic life uses oxygen. All life we see is aerobic, and thus the conceptual advances from this research will progress understanding of our world and ourselves? an important cultural goal. Advancing knowledge of such fundamental processes sits firmly in the area of the Research Priority Goal: Breakthrough Science. Postgraduate research students will be trained in sophisticated state-of-the-art theoretical and synthetic chemical methodologies. The project will enhance Australia's research capability in biological (inorganic) chemistry and promote Australia's standing in the International research community.Read moreRead less