The Australian Research Data Commons (ARDC) invites you to participate in a short survey about your
interaction with the ARDC and use of our national research infrastructure and services. The survey will take
approximately 5 minutes and is anonymous. It’s open to anyone who uses our digital research infrastructure
services including Reasearch Link Australia.
We will use the information you provide to improve the national research infrastructure and services we
deliver and to report on user satisfaction to the Australian Government’s National Collaborative Research
Infrastructure Strategy (NCRIS) program.
Please take a few minutes to provide your input. The survey closes COB Friday 29 May 2026.
Complete the 5 min survey now by clicking on the link below.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100048
Funder
Australian Research Council
Funding Amount
$630,000.00
Summary
Atmospheric integrated research on burdens and oxidative capacity. Atmospheric integrated research on burdens and oxidative capacity: No single player in the Australian research community can make a large suite of atmospheric composition measurements, while the combined capability of the community is tremendous. Providing a platform to bring this capability together is cost effective and is expected to provide strong scientific return. This defines the requirements for Atmospheric Integrated Res ....Atmospheric integrated research on burdens and oxidative capacity. Atmospheric integrated research on burdens and oxidative capacity: No single player in the Australian research community can make a large suite of atmospheric composition measurements, while the combined capability of the community is tremendous. Providing a platform to bring this capability together is cost effective and is expected to provide strong scientific return. This defines the requirements for Atmospheric Integrated Research on Burdens and Oxidative capacity (AIR-BOX) to make a valuable contribution to Australian Atmospheric Science research. This project aims to provide a suite of mobile equipment including a chemical ionisation mass spectrometer, an ultraviolet-visible radiation spectrometer, a mini micropulse lidar, an in situ Fourier transform infrared spectrometer, and a cloud condensation nuclei counter. It will be capable of remote and autonomous deployment, real-time data transfer and control, a wide range of tracer measurements, flexible configuration, and physical as well as tracer measurements.Read moreRead less
Atmospheric composition and climate change: a southern hemisphere perspective. This project addresses the science of greenhouse gases and climate change through extensive high accuracy measurements of atmospheric composition, the calibration of a new generation of satellite sensors, and the assimilation of the measured data in models of the atmosphere to elucidate the sources and sinks of greenhouse gases.
The Total Column Carbon Observing Network in the Southern Hemisphere: constraining our understanding of the carbon cycle and climate. The global carbon cycle and the distribution, sources and sinks of greenhouse gases such as carbon dioxide and methane are crucial drivers of climate change. The Total Carbon Column Observing Network (TCCON) measures the amounts of greenhouse and other trace gases in the atmosphere by solar remote sensing from the ground with unprecedented accuracy and precision. ....The Total Column Carbon Observing Network in the Southern Hemisphere: constraining our understanding of the carbon cycle and climate. The global carbon cycle and the distribution, sources and sinks of greenhouse gases such as carbon dioxide and methane are crucial drivers of climate change. The Total Carbon Column Observing Network (TCCON) measures the amounts of greenhouse and other trace gases in the atmosphere by solar remote sensing from the ground with unprecedented accuracy and precision. TCCON data are the "gold standard" for total column measurements and an essential part of greenhouse gas science. They are used to improve knowledge of the carbon cycle and future climate change, both directly and by validating global-scale satellite measurements. This project will continue to expand TCCON in the southern hemisphere and the enhanced scientific understanding it will provide.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100029
Funder
Australian Research Council
Funding Amount
$280,000.00
Summary
Ultra-trace analytical facility for earth system change . A new cutting-edge research capability will be established to safe guard Australia's natural resources and environment and to determine past variability in climate. Research results from the facility will help to guide national and international policy makers with regards to sustainable development and management of resources.
A balancing act: Resolving coastal wetland water, carbon and solute fluxes. Coastal wetlands offer an impressive capacity to regulate the Earth’s climate by altering the way carbon dioxide is extracted from the atmosphere and stored while simultaneously influencing the water cycle, thus providing ecosystem services such as carbon storage, abating flood waters, improving water quality and protecting the coastline from sea level rise. This project aims to address the current gaps in understanding .... A balancing act: Resolving coastal wetland water, carbon and solute fluxes. Coastal wetlands offer an impressive capacity to regulate the Earth’s climate by altering the way carbon dioxide is extracted from the atmosphere and stored while simultaneously influencing the water cycle, thus providing ecosystem services such as carbon storage, abating flood waters, improving water quality and protecting the coastline from sea level rise. This project aims to address the current gaps in understanding the critical exchanges of water and greenhouse gases (GHGs) combining field methodologies and hydrological models, under different climatic conditions. The intended outcomes will benefit management of GHG emissions, coastal flooding and vulnerable groundwater dependent habitats.Read moreRead less
GBR as a significant source of climatically relevant aerosol particles. Every cloud drop is formed from a microscopic aerosol particle, known as a cloud condensation nuclei (CCN). In unpolluted environments the CCN particles originate from biogenic sources. Determining the magnitude and driving factors of biogenic aerosol production in different ecosystems is crucial to the development and improvement of climate models. This project aims to determine the mechanisms of new particle production fro ....GBR as a significant source of climatically relevant aerosol particles. Every cloud drop is formed from a microscopic aerosol particle, known as a cloud condensation nuclei (CCN). In unpolluted environments the CCN particles originate from biogenic sources. Determining the magnitude and driving factors of biogenic aerosol production in different ecosystems is crucial to the development and improvement of climate models. This project aims to determine the mechanisms of new particle production from one of the biggest ecosystems in Australia, the Great Barrier Reef. It is expected that the project will establish whether marine aerosol along the Queensland coast is coral-derived and show that this aerosol can affect the CCN concentration and therefore cloud formation and the hydrological cycle.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100178
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Combining multi-platform, multi-tracer measurements with atmospheric modelling to better estimate fluxes of atmospheric constituents. The global carbon cycle and the greenhouse gases carbon dioxide and methane are important drivers of climate change. Understanding the fluxes of these gases to and from the atmosphere is crucial for understanding past, present and future climate variability. This project focuses on using simultaneous co-located measurements of greenhouse gas amounts, together with ....Combining multi-platform, multi-tracer measurements with atmospheric modelling to better estimate fluxes of atmospheric constituents. The global carbon cycle and the greenhouse gases carbon dioxide and methane are important drivers of climate change. Understanding the fluxes of these gases to and from the atmosphere is crucial for understanding past, present and future climate variability. This project focuses on using simultaneous co-located measurements of greenhouse gas amounts, together with modelling their atmospheric co-variability, to better estimate these fluxes by individual processes and on better temporal and spatial scales. In particular, co-located solar remote-sensing and in situ measurements will be combined, and the ability of the remote-sensing and in situ instruments to measure numerous gases will be exploited to improve flux estimates and atmospheric modelling.Read moreRead less
Tropospheric ozone and air quality in Australia. Ozone is an important greenhouse gas and an air pollutant that causes adverse health effects. This research will increase our understanding of changing ozone concentrations. In addition it will improve our ability to forecast episodes of poor air quality within Australia, thereby reducing the health impacts of atmospheric pollution events.
Engineering cyanobacteria for high-value flavours and fragrances production. Engineering the metabolism of cyanobacteria for industrial production of flavours and fragrances has great commercial potential. Cyanobacteria capture more than 25% of the planet’s carbon. Due to their native metabolism and capacity to express complex plant proteins, they represent an attractive Synthetic Biology platform for the biosynthesis of flavours and fragrances. Combining physiological strain characterisation an ....Engineering cyanobacteria for high-value flavours and fragrances production. Engineering the metabolism of cyanobacteria for industrial production of flavours and fragrances has great commercial potential. Cyanobacteria capture more than 25% of the planet’s carbon. Due to their native metabolism and capacity to express complex plant proteins, they represent an attractive Synthetic Biology platform for the biosynthesis of flavours and fragrances. Combining physiological strain characterisation and ‘omics studies, new Synthetic Biology strategies and models will be developed. The project aims at engineering a suite of modified freshwater and marine cyanobacteria for flavours and fragrances biosynthesis. The project aims at enabling solar biomanufacturing to underpin the emergence of an advanced Australian bioeconomy.Read moreRead less
Nanoparticles with structures that mimic enzymes for electrocatalysis. This project aims to create a new class of electrocatalysts with architectures inspired by enzymes. Electrocatalysts are the backbone of the modern energy economy. In the new electrocatalysts developed by the project, the intention is the active sites will be spatially separated from the bulk solution by nanopores, as enzymes do. This architecture allows the reaction environment to be altered from the bulk solution, active tr ....Nanoparticles with structures that mimic enzymes for electrocatalysis. This project aims to create a new class of electrocatalysts with architectures inspired by enzymes. Electrocatalysts are the backbone of the modern energy economy. In the new electrocatalysts developed by the project, the intention is the active sites will be spatially separated from the bulk solution by nanopores, as enzymes do. This architecture allows the reaction environment to be altered from the bulk solution, active transport of species to the active site and cascade reactions to be performed. This should give advantages in activity, selectivity and the ability to perform multistep reactions. The intended outcomes are better performing hydrogen fuel cells and more effective conversion of carbon dioxide into useful organic compounds.Read moreRead less