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.
Wearable thermoelectric textiles for portable microelectronics. Wearable thermoelectrics enable the power generation from the temperature difference between human body and ambient temperature by using thermoelectric effect. This project aims to design eco-friendly wearable thermoelectric textiles to realize high-efficiency solid-state power generation and meet individual needs with human comfort and health. The target is to achieve a power density in the as-designed thermoelectric textiles by th ....Wearable thermoelectric textiles for portable microelectronics. Wearable thermoelectrics enable the power generation from the temperature difference between human body and ambient temperature by using thermoelectric effect. This project aims to design eco-friendly wearable thermoelectric textiles to realize high-efficiency solid-state power generation and meet individual needs with human comfort and health. The target is to achieve a power density in the as-designed thermoelectric textiles by the optimization of materials and device design. The outcome will open up a new platform for the green and sustainable charge for portable microelectronics, which will lead to an innovative technology for energy management, which will place Australia at the forefront of wearable electronics and textile industry.Read moreRead less
Powering Next Generation Wearable Electronics: Moisture Electric Generator . This project aims to develop next generation energy harvesting device which can directly generate electricity from the moisture in the air for self-powered, wearable electronics. The goal will be achieved by developing a new class of carbon based nanomaterials and large scale printing technology, through optimizing the materials defects, printing process and electrode configuration. The expected outcomes will be new el ....Powering Next Generation Wearable Electronics: Moisture Electric Generator . This project aims to develop next generation energy harvesting device which can directly generate electricity from the moisture in the air for self-powered, wearable electronics. The goal will be achieved by developing a new class of carbon based nanomaterials and large scale printing technology, through optimizing the materials defects, printing process and electrode configuration. The expected outcomes will be new electronic materials for a wide range of end uses in wearable electronics, significant advances in self-powered, environmentally friendly devices, and commercialisation of the technology to Australian industries.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100205
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
A novel high-pressure system for multiple gas adsorption. This facility will equip researchers with analytical capabilities for research in the field of multi-gas adsorption. The facility will be of great significance to clean energy research, such as greenhouse gas emission control and hydrogen production and storage.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100119
Funder
Australian Research Council
Funding Amount
$420,000.00
Summary
Materials characterisation facility for a sustainable future. Sustainable development will require access to large-scale carbon-neutral energy production. The tools provided through this project will enable the development of new knowledge and novel materials and processes technologies that will deliver this carbon-neutral energy.
Discovery Early Career Researcher Award - Grant ID: DE220100135
Funder
Australian Research Council
Funding Amount
$438,400.00
Summary
Superhydrophobic thermally rearranged membranes for low-energy separation. This project aims to develop thermally rearranged membranes with superhydrophobicity using novel polymer chemistry and nanofibre morphology. Both water flowrate in membrane distillation and gas flowrate in carbon dioxide stripping from solvents will be increased by minimising the water vapor condensation between the nanofibers; resolving shortcomings in current energy-intensive filtration systems. This project will provid ....Superhydrophobic thermally rearranged membranes for low-energy separation. This project aims to develop thermally rearranged membranes with superhydrophobicity using novel polymer chemistry and nanofibre morphology. Both water flowrate in membrane distillation and gas flowrate in carbon dioxide stripping from solvents will be increased by minimising the water vapor condensation between the nanofibers; resolving shortcomings in current energy-intensive filtration systems. This project will provide significant benefits to Australian communities by advancing cost-effective and energy-efficient potable water production and carbon dioxide separation processes for sustainable development. The advanced materials developed can be manufactured locally and will enhance our national capability in modern manufacturing.Read moreRead less
Geological sequestration of carbon dioxide in deep saline aquifers: coupled flow-mechanical considerations. Deep saline aquifers have been routinely proposed as sites for long-term, large-scale storage of carbon dioxide (CO2) emissions, as an option to assist the abatement of global warming. This project investigates expected engineering behaviour of deep saline aquifer reservoirs and their stability following CO2 sequestration.
Structural modelling of silicon carbide-derived microporous carbon and its application in carbon dioxide capture from moist gases. The project will deliver a powerful new tool for determining the nanostructure of carbons, and will advance the modelling of fluid equilibrium, accessibility and transport within this structure. The outcomes will be crucial to the development of emerging technologies in nanofluidics, gas and electrochemical energy storage, and gas separation.
Electrochemical conversion of carbon dioxide to formic acid. This project aims to develop economical and scalable carbon dioxide electrochemical technologies to convert carbon dioxide in blast furnace flue gas to formic acid as a value-added product in steel-making plants. The project expects to develop new electrochemical catalysts, to optimise the structure of electrodes and ultimately improve carbon dioxide conversion efficiency and reaction selectivity towards formic acid. The expected outco ....Electrochemical conversion of carbon dioxide to formic acid. This project aims to develop economical and scalable carbon dioxide electrochemical technologies to convert carbon dioxide in blast furnace flue gas to formic acid as a value-added product in steel-making plants. The project expects to develop new electrochemical catalysts, to optimise the structure of electrodes and ultimately improve carbon dioxide conversion efficiency and reaction selectivity towards formic acid. The expected outcomes of this project will provide an efficient and economically viable electrochemical technology to convert carbon dioxide to a valuable product such as formic acid or syngas, with the potential to significantly reduce the emission of carbon dioxide from steel-making processes and coal-fired power plants.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100326
Funder
Australian Research Council
Funding Amount
$425,231.00
Summary
Mass transfer enhancement for hydrate based carbon capture and cold storage. This project aims to generate the knowledge and techniques required to increase carbon dioxide (CO2) uptake in hydrate based carbon capture from current levels of 15.4% to up to 90% of its rated capacity. This marked improvement stems from identification of the mechanism of CO2-water mass transfer in CO2 hydrate formation and engineering of structurally modified porous hydrogels as the substrate of CO2 hydrates. Encapsu ....Mass transfer enhancement for hydrate based carbon capture and cold storage. This project aims to generate the knowledge and techniques required to increase carbon dioxide (CO2) uptake in hydrate based carbon capture from current levels of 15.4% to up to 90% of its rated capacity. This marked improvement stems from identification of the mechanism of CO2-water mass transfer in CO2 hydrate formation and engineering of structurally modified porous hydrogels as the substrate of CO2 hydrates. Encapsulation will be developed in a way that CO2 may be transported by CO2 hydrates in a concentrated form. Successful completion of the project will offer technical evaluation of a novel CO2 capture and transport solution with lower operational energy consumption and capital cost than incumbent carbon capture technologies.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101151
Funder
Australian Research Council
Funding Amount
$454,532.00
Summary
Harnessing social norms to find a socially acceptable energy transition. This project aims to discover the potential of social norms to enable energy-producing communities to explore and define a socially acceptable energy transition. By implementing and evaluating a new social norm change intervention in the Upper Hunter region, this project expects to generate new knowledge about what matters most to communities facing transition, and how norms, identities, and networks interact to enable or c ....Harnessing social norms to find a socially acceptable energy transition. This project aims to discover the potential of social norms to enable energy-producing communities to explore and define a socially acceptable energy transition. By implementing and evaluating a new social norm change intervention in the Upper Hunter region, this project expects to generate new knowledge about what matters most to communities facing transition, and how norms, identities, and networks interact to enable or constrain change. Outcomes include direct input to energy transition planning, enhanced collaboration with policy and civil society, and new international research networks. This should provide significant benefits by helping Australian communities and policy-makers navigate the local impacts of global energy transition.Read moreRead less