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.
Turning homogeneous catalysts into heterogeneous catalysts: Robust linking of organometallic complexes onto inert carbon supports. Improvement in the sustainability of fine chemical synthesis is urgently required to meet the increasing demand for new pharmaceuticals. This project will develop new approaches to catalyst immobilisation, to enhance catalyst recovery, as well as to the characterisation of such catalysts for understanding structure and mechanism.
Geometry variation and coupling of single gold nanorods for highly efficient, one-photon and two-photon luminescent markers. The search for highly efficient, non toxic and stable luminescence markers is continuing for many applications in bio- and nano-photonics. The project's study of gold nanorod luminescence is designed to fundamentally understand and control the luminescence quantum efficiency of gold nanorod and ultimately unveil its potential as the future marker.
Atomic Structure and Stability of Nanocrystal Facets. This project aims to provide a ‘toolkit’ to understand and grow nanocrystal shapes to achieve desired optical properties. The facets of a metal nanocrystal comprise just a few atoms, which are pivotal to its growth and properties. This project aims to develop methods to measure the location and stability of these atoms to understand the factors controlling their assembly and to understand their impact on the properties of the nanocrystal. It ....Atomic Structure and Stability of Nanocrystal Facets. This project aims to provide a ‘toolkit’ to understand and grow nanocrystal shapes to achieve desired optical properties. The facets of a metal nanocrystal comprise just a few atoms, which are pivotal to its growth and properties. This project aims to develop methods to measure the location and stability of these atoms to understand the factors controlling their assembly and to understand their impact on the properties of the nanocrystal. It plans to correlate atomic structure and corresponding optical excitations with unprecedented spatial and energy resolution. Combining these advances, the project aims to relate nanofacet chemistry, structure, stability and optical excitations to deliver a new understanding of optical properties and their control.Read moreRead less
Photonic circuitry from the noble metals: nanocrystal coupling. Linear arrays of crystalline nanoparticles are able to act in a manner analogous to an optical fibre, but with much smaller dimensions. This project will investigate the underlying principles of waveguiding within the arrays and aims to build and test sections of such optical fibres, thereby assessing their use in optical circuits.
Harnessing Asymmetry in Hybrid Metal Nanocrystal Assemblies. The interaction between metallic nanoparticles creates highly enhanced, localised electric fields and has recently emerged as a strategic area widely applicable across physics, chemistry and biology for sensing, optoelectronics and optical films. The novel optical signatures of larger, highly symmetric nanoparticle assemblies may be drastically changed by breaking the structural symmetry, leading to unique phenomenon such as Fano-like ....Harnessing Asymmetry in Hybrid Metal Nanocrystal Assemblies. The interaction between metallic nanoparticles creates highly enhanced, localised electric fields and has recently emerged as a strategic area widely applicable across physics, chemistry and biology for sensing, optoelectronics and optical films. The novel optical signatures of larger, highly symmetric nanoparticle assemblies may be drastically changed by breaking the structural symmetry, leading to unique phenomenon such as Fano-like resonances. This project aims to extend metal nanoparticle assemblies to include fluorophores in well-defined positions, creating an inherent and switchable symmetry breaking. Inclusion of additional functionality into such structures is essential for their use in smart optical films and switchable devices.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL100100117
Funder
Australian Research Council
Funding Amount
$2,713,582.00
Summary
Molecular Plasmonics - From Single Electrons to Quantum Catalysis and Optical Logic Gates. After a decade of basic research, Nanotechnology is now entering its most disruptive phase. New nanoscale phenomena are being exploited and converted into viable technologies. Plasmonics - the manipulation of light using metal nanostructures - is one of the most promising of these. Plasmonics will enable scientists to achieve optical computing, reach higher data storage densities, and synthesize better cat ....Molecular Plasmonics - From Single Electrons to Quantum Catalysis and Optical Logic Gates. After a decade of basic research, Nanotechnology is now entering its most disruptive phase. New nanoscale phenomena are being exploited and converted into viable technologies. Plasmonics - the manipulation of light using metal nanostructures - is one of the most promising of these. Plasmonics will enable scientists to achieve optical computing, reach higher data storage densities, and synthesize better catalysts. Other applications include bio-sensing and rapid pathogen detection. To realise these potential outcomes, a leading international cluster focussing on plasmonics will be set up and this cluster will link state-of-the-art materials science, instrumentation and theory.Read moreRead less
Nanoparticle inks for electronic applications employing nanostructured thin-films. The development of next-generation technologies requires careful engineering of materials at the nanoscale. Using nanoparticle inks, many of the engineering difficulties which exist at these length scales can be overcome, thus allowing for technologies such as thin-film solar cells to become cheaper and more efficient.
The mechanism of scale formation and inhibition in alkaline industrial process streams. Scaling, which reduces flow and heating efficiency, is a serious problem in single stream alumina Bayer plants. This project will potentially save the Australian alumina industry many tens of millions of dollars a year by the development of more effective on-line scale mitigation strategies based on the fundamental understanding of the processes involved.
Sustainable surfactants from Australian oilseeds. This project aims to develop a new generation of sustainable surfactants utilising Australian-grown oilseed feedstocks. These molecules are designed to replace current materials made from petroleum and palm oil, to fulfil a key role as the next generation of bio-resourced detergents and emulsifiers. The work seek to develop a library of new molecules to better understand the relationship between molecular structure and performance, through cuttin ....Sustainable surfactants from Australian oilseeds. This project aims to develop a new generation of sustainable surfactants utilising Australian-grown oilseed feedstocks. These molecules are designed to replace current materials made from petroleum and palm oil, to fulfil a key role as the next generation of bio-resourced detergents and emulsifiers. The work seek to develop a library of new molecules to better understand the relationship between molecular structure and performance, through cutting edge lab testing and utilising national infrastructure, guiding the use of new components in formulating new products. It is anticipated that the surfactants generated will find uses in household cleaning and personal care products, providing high value chemicals from key Australian crops.Read moreRead less
Food structure design. Food structure design. This project aims to use fundamental studies in multi-scale rheology and biotribology, surface sciences, soft matter physics and protein chemistry to develop new measurement capabilities and knowledge for rational food structure design. This research is intended to enable researchers and industry to quantify how oral processing (including saliva) transforms food during consumption, and to provide new instrumental measurements and know-how that assist ....Food structure design. Food structure design. This project aims to use fundamental studies in multi-scale rheology and biotribology, surface sciences, soft matter physics and protein chemistry to develop new measurement capabilities and knowledge for rational food structure design. This research is intended to enable researchers and industry to quantify how oral processing (including saliva) transforms food during consumption, and to provide new instrumental measurements and know-how that assists in defining sensory percepts in dairy foods and beverages such as creaminess in full, reduced or non-fat systems and grittiness in high protein systems.Read moreRead less