Grants & Opportunities

Grant program for theatre companies and organisations

Provides ophthalmology Fellowships to train future eye-care specialists at Sydney Eye Hospital

Funds research projects, equipment, and patient care initiatives

Scholarships for registered nurses to complete a Master of Cancer & Haematology Nursing at the University of Sydney, building specialist skills in cancer care

Scholarships for Indigenous law students and legal professionals

Field-intensive coral reef research fellowships for PhD students and early-career researchers

Competitive research grant program for Sanfilippo research projects

Supports visits by international artists, weavers, and academics to contribute to the advancement of tapestry in Australia.

Supports international weaver exchanges.

Provides emergency grants to members and their families when other lines of support are exhausted.

International Tax in the Digital Age: A Blueprint for Allocating Profits. This project aims to investigate tax avoidance by multinational enterprises in the age of the digital economy. It addresses the difficult problem of determining the location in which profits are made. The project expects to generate new knowledge in international tax by developing a blueprint for allocating profits of multinational enterprises between jurisdictions that aligns with profit making activity and reduces international tax avoidance. A systematic structure for allocating profits of multinational enterprises will address the important problem of tax base erosion caused by profit shifting. This will provide the significant benefit of developing a major tool in securing Australia’s revenue base in the digital age.. Scheme: ARC Future Fellowships. Field: 1801 - Law. Lead: Prof Kerrie Sadiq

Understanding nutritional interactions for targeted microbiome manipulation. This project aims to identify how microbial communities, known as microbiomes, can be effectively manipulated to the benefit of their host. Microbiome manipulation has been in the spotlight as a potential solution to maintain or improve the health of several hosts, from threatened coral species to livestock and humans, but the development of industry-scale strategies has been slow. This project proposes to chart the nutritional interactions among microorganisms and to identify cascade effects of microbiome manipulation. This will generate fundamental knowledge on the biological processes underlying community stability and malleability, which will ultimately help engineering optimised microbiomes.. Scheme: Discovery Early Career Researcher Award. Field: 0605 - Microbiology. Lead: Dr Vanessa Rossetto Marcelino

Smart Optimisation of Functionally Graded Porous Structures. This project aims to develop a novel smart optimisation method for shaping the porosity geometries of metal foams for design requirements. Although these functionally graded porous structures have superior engineering properties, efficient examination methods to understand the mechanical behaviour of irregular graded porosities are lacking. Expected outcomes of this project include the expansion of fundamental knowledge in porous media and new technologies to build stronger and lighter multifunctional structural components. The project will provide significant benefits, including enhanced manufacturing capacities of local industries to fabricate metal foam products, new job opportunities in a growing market, and less carbon emissions.. Scheme: Discovery Early Career Researcher Award. Field: 0905 - Civil Engineering. Lead: Dr Da Chen

Rare Earth Metal Separation by Polymer Inclusion Membranes. The project aims to develop a novel hydrometallurgical method for the separation of the rare earth metals dysprosium and terbium from mixed rare earth metal solutions using polymer inclusion membranes with a crosslinked or non-crosslinked polymer backbone. These metals are crucial for the manufacturing of advanced technology products. The membrane-based method is expected to offer significant advantages over the currently used solvent extraction methods by eliminating the use of solvents and conducting the separation as a continuous process where the extraction and back-extraction steps take place simultaneously. These advantages are expected to make the separation process more cost-effective and drastically reduce its environmental impact.. Scheme: Linkage Projects. Field: 0904 - Chemical Engineering. Lead: Prof Spas Kolev

Enhancing marine bathymetry using new generation satellite sensors. Highly accurate marine bathymetry are currently lacking in 72% of the global ocean including around Australia, particularly in shallow seas and near-shore coastal zones, contributing to various navigation and marine safety accidents. Ship surveys of the seafloor are time-consuming and expensive. Satellite altimetry data provide an alternative solution. This project will improve Australia’s marine bathymetry by using spatially comprehensive and unprecedented data from new radar and laser satellite sensors. We aim to develop techniques for integration of the new data with other independent data sources, producing the most precise marine bathymetry for coastal terrain mapping, marine transport and safety management.. Scheme: Discovery Projects. Field: 0909 - Geomatic Engineering. Lead: Hon A/Prof Xiaoli Deng

Using assisted evolution to win the war against invasive species. Invasive species disrupt ecosystem functioning, causing severe economic costs. This project investigates the use of native insects, alongside assisted evolution, as a novel approach to control invasive plants. Combining experimental and observational data we aim to accelerate adaptation already underway and entrained by selection from interactions between invasive plants and Australian insects. These data will not only address unresolved questions in evolutionary biology but will also provide knowledge on the role native insects can play in the biocontrol of invasive weeds. This will be crucial for conservation managers and agricultural practitioners dealing with plant movement and/or crop development under ongoing environmental change.. Scheme: Discovery Projects. Field: 0501 - Ecological Applications. Lead: Prof Johannes Le Roux

Molecular Thermoelectric Materials: A New Hot Topic. This project aims to use the principles of chemistry and molecular electronics to synthesize and study molecules able to directly convert waste heat into electricity through the Seebeck effect. This project expects to generate new knowledge concerning the wire-like properties of molecules and conditions that lead to a high Seebeck coefficient, together with interference effects to suppress thermal conductance. Expected outcomes of this project include a deeper understanding of chemical structure - molecular electronic property relationships, and enhanced international collaboration with the UK. This should provide benefits in terms of low-cost conversion of waste heat to electrical energy. . Scheme: Discovery Projects. Field: 1007 - Nanotechnology. Lead: Prof Paul Low

Judges' work, place and psychological health - a national view. This project aims to address the human, juridical and financial costs of judicial officers’ work-related psychological harm. This harm is implicated in early retirement, sick leave and suicide. It threatens appropriate courtroom conduct, procedural fairness and impartial adjudication. The project seeks to generate new knowledge of the stress judicial officers experience and the individual and institutional mechanisms for managing stressors, combining socio-legal and psychological approaches. Expected outcomes include evidence-based understandings to inform recruitment and retention strategies specific to this highly specialized workforce. This should provide significant benefits for judges’ work capacities and courts' delivery of justice.. Scheme: Discovery Projects. Field: 1801 - Law. Lead: Prof Prudence Vines

High-value functional ingredients from bean processing waste. Legumes are considered highly nutritious and sustainable food. Accordingly, there is a steady growth in the consumption of legumes worldwide, including in Australia. Due to lengthy soaking and cooking times, consumers prefer ready-to-eat canned legumes. The current processing technologies are energy and water-intensive and generate considerable waste. This project investigates the application of non-thermal technologies to reduce processing time, water and energy use and enable the recovery of valuable polyphenols and soluble dietary fibres normally lost in the wastewater. This knowledge will lead to sustainable beans processing, delivering improved productivity to Australian manufacturers and quality food to Australian consumers.. Scheme: Linkage Projects. Field: 0908 - Food Sciences. Lead: A/Prof Sushil Dhital

Strain-stabilised perovskite optoelectronics: from fundamentals to devices. This project aims to develop deep structure-property relationships and strain engineering protocols to generate stable forms of the emerging inorganic halide perovskite semiconductors, which are promising for next-generation solar cells and light emitting diodes. This project expects to arrive at working light emitter and detector prototypes via a three-dimensional, multi-length scale strain engineering approach that utilises materials processing techniques already used in the semiconductor industry. The expected outcomes include the development of new stabilisation methods which are compatible with facile and scalable device processing, which will directly impact the success of future perovskite optoelectronic devices and technologies.. Scheme: Discovery Early Career Researcher Award. Field: 5104 - Condensed Matter Physics. Lead: Dr Julian Steele

New Silent Anchors for Floating Offshore Wind Turbines in Calcareous Sand . Reliable wind energy sites are in deeper waters and require offshore floating structures to harness the wind energy. Such floating structures require a reliable anchoring system that is secure and environmentally friendly. Calcareous sands, rich in carbonate content, pose unique challenges with their behaviour difficult to predict. In this project, a novel silent anchoring system is investigated that can be installed with minimum noise and vibration compared to more traditional counterparts. Through the state of the art development in numerical modelling and centrifuge modelling, this project will advance Australian Science and Practice in designing floating wind turbines in carbonate rich soils offshore and help energy transition.. Scheme: Discovery Projects. Field: 4005 - Civil Engineering. Lead: Prof Yuxia Hu

Enabling wider use of mechanistic models for biodiversity forecasts . Forecasting species distributions is challenging yet necessary. The pattern-based models commonly used are error-prone. Mechanistic models, best equipped for the task, are limited by lack of data. This project aims to enable wider use of mechanistic models by developing new methods for dealing with incomplete trait data and uncertainty. It expects to generate new knowledge about how species’ traits define the environments in which they persist. Anticipated outcomes include enhanced capacity to apply mechanistic models to conservation problems, methods for communicating uncertainties and models for tens of species of immediate conservation interest. This will enable more reliable biodiversity forecasts, supporting better decision-making. . Scheme: Discovery Projects. Field: 4104 - Environmental Management. Lead: Prof Michael McCarthy

Novel source of excited metastable atoms for Atom Trap Trace Analysis. This project aims to understand and to control light-induced processes in atoms by using finely shaped and tailored laser pulses, focusing on efficient production of excited metastable atoms. This is critical for efficient Atom Trap Trace Analysis, the most advanced technique for dating ground water and geological samples. Expected outcomes of this project include new and enhanced knowledge of physics of light-matter interactions, developing an efficient, clean source of excited metastable atoms, and integrating that source into the Australian National Facility for dating geological samples. This should provide significant benefits, such as significant improvement of operational efficiency and productivity of that facility.. Scheme: Discovery Projects. Field: 5102 - Atomic, Molecular and Optical Physics. Lead: Prof Igor Litvinyuk

A Biologically Responsive and Anatomically Authentic Human Nasal Model. As respiratory conditions caused by pollutants and viruses become more prevalent, human nasal models to study infection/protection mechanisms and nasal drug/vaccine delivery are increasingly important. This project aims to develop a world-first human nasal model to mimic both anatomical and biological aspects of the nasal cavity and predict the distribution and deposition of fine particles and the resultant biological response from the nasal mucosa. The aim is to overcome a key fabrication challenge - to 3D print an anatomically accurate nasal construct with a porous wall on which to grow and mature functional nasal tissue that lines a nasal cavity wall. The benefit would be enabling faster development of more targeted drugs and vaccines.. Scheme: Discovery Projects. Field: 4003 - Biomedical Engineering. Lead: Prof Yi-Chin Toh

Migration-Dependent Signalling in Macrophages . The project aims to investigate a mechanism of communication used by immune cells to guide each other towards sites of damage. The project will characterise newly revealed cell signalling membrane trails left behind by migrating cells, utilising biochemistry, innovative imaging and microscopy and a transparent zebrafish model to view cell migration through living tissues. Expected outcomes include new fundamental knowledge in the area of immune cell migration with relevance to the basic biology of inflammation, repair and regeneration and new innovations for cell imaging. Significant benefits are expected to arise from this new knowledge and from advanced skills training and improved national capabilities in bio-imaging and analysis.. Scheme: Discovery Projects. Field: 3101 - Biochemistry and Cell Biology. Lead: Prof Jennifer Stow