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.
Ultra-high mobility Dirac semimetal nanostructures for solid state devices. This project aims to develop novel Dirac semimetal nanostructures and determine their structural and chemical characteristics to ultimately assemble high-performance devices. The growth of band-engineered nanostructures and understanding their evolution, fine structure and unique properties are key steps for developing high-performance nanostructure-based devices. The new knowledge and skills developed in this project wi ....Ultra-high mobility Dirac semimetal nanostructures for solid state devices. This project aims to develop novel Dirac semimetal nanostructures and determine their structural and chemical characteristics to ultimately assemble high-performance devices. The growth of band-engineered nanostructures and understanding their evolution, fine structure and unique properties are key steps for developing high-performance nanostructure-based devices. The new knowledge and skills developed in this project will greatly enhance the knowledge base of nanoscience and nanotechnology, and will have a significant impact on practical applications of nanostructure-based devices. This project will underpin the development of next-generation electronic nanomaterials that will enhance the long-term viability of Australia’s high-technology industries.Read moreRead less
Plasma-assisted on-surface assembly for hydrogen production and beyond. This project aims to discover how to catalyse the formation and control the structure of functional materials with atomic precision using plasmas. New mechanisms of ultra-fast, plasma-catalytic on-surface nanoasembly will translate into energy-efficient, scalable digital fabrication of subnano-cluster and single-atomic-site catalysts over large 3D surface areas, tailored for advanced electrocatalysis. The outcomes including ....Plasma-assisted on-surface assembly for hydrogen production and beyond. This project aims to discover how to catalyse the formation and control the structure of functional materials with atomic precision using plasmas. New mechanisms of ultra-fast, plasma-catalytic on-surface nanoasembly will translate into energy-efficient, scalable digital fabrication of subnano-cluster and single-atomic-site catalysts over large 3D surface areas, tailored for advanced electrocatalysis. The outcomes including new concepts and insights into synergistic action of plasmas and solid surfaces will bridge atomic-scale materials formation and digital fabrication at industrial scales. The benefits including the new nanofabrication platform and clean energy will go beyond the demands of digital manufacturing and hydrogen economy. Read moreRead less
Cost-effective metal selenide materials for solid-state devices. Thermoelectric materials, directly converting thermal energy into electrical energy, offer a green and sustainable solution for the global energy dilemma. This project aims to develop cost-effective metal selenide materials for high-efficiency solid-state devices using a novel industry-level approach, coupled with nanostructure and band engineering strategies. The key breakthrough is to design high-performance metal selenide thermo ....Cost-effective metal selenide materials for solid-state devices. Thermoelectric materials, directly converting thermal energy into electrical energy, offer a green and sustainable solution for the global energy dilemma. This project aims to develop cost-effective metal selenide materials for high-efficiency solid-state devices using a novel industry-level approach, coupled with nanostructure and band engineering strategies. The key breakthrough is to design high-performance metal selenide thermoelectric materials with engineered chemistry and unique structures for new generation thermoelectrics. The expected outcomes will lead to an innovative technology for harvesting electricity from waste heat or sunlight, which will place Australia at the forefront of energy and manufacturing technologies.Read moreRead less
Inorganic/organic Hybrids for flexible thermoelectric generators. Flexible thermoelectric generators can directly harvest electricity from body heat, offering a new technology for wearable electronics, but their unsatisfied performance limits their applications. This project aims to design high-efficient and mechanically robust flexible thermoelectric devices based on novel hybrids with quantum dots and conducting polymers as key components. The key breakthrough is to establish unique devices wi ....Inorganic/organic Hybrids for flexible thermoelectric generators. Flexible thermoelectric generators can directly harvest electricity from body heat, offering a new technology for wearable electronics, but their unsatisfied performance limits their applications. This project aims to design high-efficient and mechanically robust flexible thermoelectric devices based on novel hybrids with quantum dots and conducting polymers as key components. The key breakthrough is to establish unique devices with record-high thermoelectric efficiency and to illustrate the underlying mechanisms for searching new-type flexible thermoelectrics. The expected outcomes will lead to innovative technology for energy conversion and advanced manufacturing and place Australia at the forefront of energy and manufacturing fields.Read moreRead less
Next generation easy-clean lenses by robust liquid-repellent nanotextures. This project aims to produce better performing self-cleaning lenses, which are less likely to get dirty and are easy to clean. It will develop water and oil repellent coatings with superior optical transparency and mechanical, solvent and UV stability for both hard coated and anti-reflection coated optical lenses. Engineering of stable, ultra-liquid repellent nanomaterials on transparent surfaces will create a foundation ....Next generation easy-clean lenses by robust liquid-repellent nanotextures. This project aims to produce better performing self-cleaning lenses, which are less likely to get dirty and are easy to clean. It will develop water and oil repellent coatings with superior optical transparency and mechanical, solvent and UV stability for both hard coated and anti-reflection coated optical lenses. Engineering of stable, ultra-liquid repellent nanomaterials on transparent surfaces will create a foundation of knowledge for the industrial development of the future generation of easy care coatings, with vast application potential.Read moreRead less
Bioinspired photo–iontronic membranes for smart neuron-mimicking systems. The project aims to address key fundamental questions about the development of bioinspired artificial nanochannels that can precisely mimic current signals and functionalities in neurons. This is expected to generate fundamental and applied knowledge in bioengineered photo–iontronic systems, harnessing a multidisciplinary approach to engineer materials with precisely tailored properties at the nanoscale for unprecedented d ....Bioinspired photo–iontronic membranes for smart neuron-mimicking systems. The project aims to address key fundamental questions about the development of bioinspired artificial nanochannels that can precisely mimic current signals and functionalities in neurons. This is expected to generate fundamental and applied knowledge in bioengineered photo–iontronic systems, harnessing a multidisciplinary approach to engineer materials with precisely tailored properties at the nanoscale for unprecedented dynamic control over ionic current through responsive, adaptable neuron-mimicking nanopores. Anticipated outcomes are advanced materials, integrated into smart architectures to overcome the limitations of solid-state systems for the next generation of integrated circuits, bio-interfacial sensors, and energy generators.Read moreRead less
Nanofluid stickiness will transform the Energy and Biotechnology Industries. This project aims to determine how minuscule particles behave on surfaces with different nano-architecture. Modern technologies already use nanodecorated materials to lubricate engines or capture tumour cells. Yet, their potential in applications for sustainable catalysis, gas treatment or water splitting cannot be realised until we understand how nano-objects adsorb to surfaces with features of comparable size. The exp ....Nanofluid stickiness will transform the Energy and Biotechnology Industries. This project aims to determine how minuscule particles behave on surfaces with different nano-architecture. Modern technologies already use nanodecorated materials to lubricate engines or capture tumour cells. Yet, their potential in applications for sustainable catalysis, gas treatment or water splitting cannot be realised until we understand how nano-objects adsorb to surfaces with features of comparable size. The expected outcomes include new methods, models and a workable map of protein adsorption allowing us to 1) create advanced substrates for targeted applications and 2) understand existing phenomenon governed by naturally occurring nanoroughness. It will benefit manufacturing in fields ranging from biology to energy production.Read moreRead less
An account of wetting phenomena on nano-engineered surfaces. This project aims to provide researchers and industry with a toolbox to predict wetting behaviour on surfaces with nanoscale topography. A combined experimental and numerical study will lead to the discovery of the mechanisms by which topographical and chemical properties of the surface trigger the formation of nanostructure-induced air pockets and how these phenomena determine surface wettability. This will provide significant benefi ....An account of wetting phenomena on nano-engineered surfaces. This project aims to provide researchers and industry with a toolbox to predict wetting behaviour on surfaces with nanoscale topography. A combined experimental and numerical study will lead to the discovery of the mechanisms by which topographical and chemical properties of the surface trigger the formation of nanostructure-induced air pockets and how these phenomena determine surface wettability. This will provide significant benefits, as the predictive surface-wettability model will enhance controllability and productivity of diverse manufacturing processes and lead to new applications, high-value products and economic benefits in mining, energy, electronics, biomedicine and other fields.Read moreRead less