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.
Tuning the electrolytes for high efficiency solar splitting of water. This project will develop a new technology that uses ionic liquids and sunlight to split water into hydrogen and oxygen to be used as a clean fuel. Australia has abundant sunlight, is very close to the growing energy markets of the Asia-Pacific region, and is ideally placed to benefit from this new technology.
Luminophores and photochromes: towards molecular componentry. This project aims to enhance current knowledge of luminogenic and photochromic molecules, including self-assembled structures, and materials composed thereof, by constructing a computationally guided compound library. Translation of primary outcomes towards utility in emerging technologies including passive light harvesting from transparent surfaces, bio-sensors and photo-responsive devices will be pursued in collaboration with both a ....Luminophores and photochromes: towards molecular componentry. This project aims to enhance current knowledge of luminogenic and photochromic molecules, including self-assembled structures, and materials composed thereof, by constructing a computationally guided compound library. Translation of primary outcomes towards utility in emerging technologies including passive light harvesting from transparent surfaces, bio-sensors and photo-responsive devices will be pursued in collaboration with both academia and industry. The expected outcomes from this project include the creation of opportunities to explore the manufacture and commercialisation of high-value products with Australian industry. This will provide significant benefits, such as reduction in the carbon footprint of homes, businesses and other applicable structures due to passive power generation, while creating jobs and up-skilling the workforce.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100158
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
Supercontinuum fibre laser consortium for the chemical and materials sciences. A supercontinuum fibre laser facility will be established across nodes at The University of Adelaide and The University of Melbourne, and used to probe the chemical basis of photosynthesis, explore the properties of organic solar cell materials and biomaterials, develop efficient metal catalysts, and detect metal vapours in gases.
Computer-Aided Design of High-Performance Photocatalysts for Solar Hydrogen Production Based on Red Titanium Dioxide. Large-scale generation of energy by solar conversion is critical for future sustainability. This project aims to develop high performance materials to efficiently convert solar energy to hydrogen - a clean fuel. Starting from the newly developed material red titanium dioxide, novel strategies for improved photocatalytic materials will be proposed and evaluated by advanced computa ....Computer-Aided Design of High-Performance Photocatalysts for Solar Hydrogen Production Based on Red Titanium Dioxide. Large-scale generation of energy by solar conversion is critical for future sustainability. This project aims to develop high performance materials to efficiently convert solar energy to hydrogen - a clean fuel. Starting from the newly developed material red titanium dioxide, novel strategies for improved photocatalytic materials will be proposed and evaluated by advanced computational approaches. Key issues for solar-to-hydrogen conversion will be clarified. The materials, knowledge and strategies achieved by this project will dramatically enhance current solar technology and in particular will advance the development of low-cost hydrogen production from water. Read moreRead less
Towards ab initio molecular dynamics simulations of proton and electron transfer processes. Electrochemical technologies seek design capabilities to enable the discovery of novel electrolytes with valuable properties. This project will develop new advanced computational methods to understand electron and proton transfer in electrolytes and thereby allow us to enhance performance of electrochemical devices and control metal deposition.
To identify and to understand highly reactive surfaces for solar hydrogen production. This project aims to develop advanced technology to produce hydrogen - carbon-free fuel - from water with sunlight as the only energy input. Using clean energy to replace fossil fuels can help address the issues of energy supply and reduce carbon emissions, which is critically important for a sustainable Australia.
Discovery Early Career Researcher Award - Grant ID: DE150100427
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
All-in-one Functional Nanocrystal Inks for Printed Inorganic Solar Cells. At present, manufacturing solar panels involves expensive high temperature and high vacuum processes. The bottleneck to cheaper solar power is the ability to design new methods of manufacturing. The ability to print the active components of a solar cell is an excellent way to mitigate these costs. This project aims to focus on developing the knowledge to print the most crucial component of a solar cell - the light absorbin ....All-in-one Functional Nanocrystal Inks for Printed Inorganic Solar Cells. At present, manufacturing solar panels involves expensive high temperature and high vacuum processes. The bottleneck to cheaper solar power is the ability to design new methods of manufacturing. The ability to print the active components of a solar cell is an excellent way to mitigate these costs. This project aims to focus on developing the knowledge to print the most crucial component of a solar cell - the light absorbing layer. Innovative nanoscience will be used to develop novel solar inks composed of tiny semiconductor crystals. The formulation and transformation of these inks into efficient semiconductor light absorbing layers, with a clear view to cheaper printed solar cells, will be the key objective of this project.Read moreRead less
Engineered nanoassmblies for energy conversion. This research will lead to development of clean energy technology that can compete with the traditional energy sources without subsidies, and facilitate long-term solution to the energy crisis and global warming. It will also bring significant benefit to Australian industries and economy and assist achievement of renewable energy target.
Nano-fibrous structure for high-performance organic photovoltaic thin films. This project aims to create nano-fibrous active thin films with high charge mobility for organic photovoltaic (OPV) devices, using a method inspired by molecular gelation. The significance of this project is that it addresses a major bottleneck, i.e. poor charge generation and transport, that limits the efficiency of OPV devices. The outcomes will provide insights into the crucial factors that affect the self-assembly o ....Nano-fibrous structure for high-performance organic photovoltaic thin films. This project aims to create nano-fibrous active thin films with high charge mobility for organic photovoltaic (OPV) devices, using a method inspired by molecular gelation. The significance of this project is that it addresses a major bottleneck, i.e. poor charge generation and transport, that limits the efficiency of OPV devices. The outcomes will provide insights into the crucial factors that affect the self-assembly of organic semiconducting materials, and the influences of nano-fibrous structure on the charge mobility and efficiency of an OPV device. The outcomes will greatly facilitate the development of highly efficient, lightweight and low-cost solar energy harvesting devices to reduce our carbon footprint.Read moreRead less
Wet Particulate Materials - Flow or Fracture? Most advanced materials are produced from starting materials in the form of fine particles. Powders, especially in ceramic engineering, are first processed wet into near-final shape. Improved understanding of the fracture of particle networks is critical in order to process nano-sized advanced ceramic materials for use in solar energy harvesting and extreme heat engine applications as well as minimising drying cracks in paints and coatings. The resea ....Wet Particulate Materials - Flow or Fracture? Most advanced materials are produced from starting materials in the form of fine particles. Powders, especially in ceramic engineering, are first processed wet into near-final shape. Improved understanding of the fracture of particle networks is critical in order to process nano-sized advanced ceramic materials for use in solar energy harvesting and extreme heat engine applications as well as minimising drying cracks in paints and coatings. The research aims to identify the fundamental link between particle network strength and structure and the fracture of wet powder bodies. The microscopic mechanisms that control the behaviour will be investigated with a particular focus on toughening mechanisms including the influence of plasticity.Read moreRead less