Grants & Opportunities

Supporting the sustainability of Australia's local news ecosystem. This project aims to understand how Australia’s main public broadcaster, the ABC, can best support public interest journalism in rural and regional communities, with a specific focus on fragile and underserved areas of the nation’s local news ecosystem. The project will develop new knowledge around media power and how news providers can work together to secure the sustainability of local news. Expected outcomes include a framework to identify and define areas of news need, an assessment of existing interventions and road-tested approaches to improve information quality. The project should provide benefits by supporting forms of local journalism that ultimately enhances the demographic health and social fabric of small towns and cities. . Scheme: Linkage Projects. Field: 4701 - Communication and Media Studies. Lead: Prof Kristy Hess

Thermoelectric devices for high-performing localised coolers. This project aims to develop a lightweight, low-energy-consumption, and high-durability wearable thermoelectric cooler for localised cooling using a novel industry-led approach, coupled with device design and materials engineering strategies. The key breakthrough expected is to design wearable thermoelectric coolers by using flexible substrates and thermoelectric materials with engineered chemistry and unique structures for achieving localised, instant, and controllable cooling with super low power input for personal usage in building and mining industry. Expected outcomes include innovative technologies for achieving high-efficiency cooling, which will provide significant economic and commercial benefits for Australia.. Scheme: Linkage Projects. Field: 4016 - Materials Engineering. Lead: Prof Zhi-Gang Chen

Surveillance and sampling to maintain absence of pests and diseases. This project aims to develop empirically validated statistical and mathematical methods for industry and government to deliver more efficient biosecurity surveillance programs. The project endeavours to enhance biosecurity at the border and within Australia, while minimising the costs and burden of testing. Expected project outcomes include effective surveillance and sampling for high-priority threats, accessible software for decision-makers, and generalisable approaches to address rapidly increasing biosecurity risks. Significant benefits include maintaining absence of key pathogens and pests in Australia.. Scheme: Linkage Projects. Field: 4905 - Statistics. Lead: Prof Kathryn Glass

Transforming harvest surplus into nutritious meals for food relief. The project aims to transform currently wasted harvest surplus into nutritious shelf-stable plant-based products for the food-relief sector. It integrates novel social-enterprise models with advanced food manufacturing and bespoke training and volunteering opportunities for food insecure individuals, to facilitate their pathway out of food insecurity. In close collaboration with food relief supply-chain provider Foodbank SA and policymaker Green Industries SA, the project will tackle two major problems for Australia – food insecurity and food waste – through systems thinking and leveraging underused resources, while building collaborations across academia and multiple industry sectors.. Scheme: Mid-Career Industry Fellowships. Field: 3506 - Marketing. Lead: Prof Svetlana Bogomolova

Novel minerals and mix design in low embodied carbon concrete products . Research and development in materials and mix design for concrete building products will target utilisation of abundant and low cost mineral materials including natural clay, hard rock quarry fines and unclassified fly ash resources. New mix design and preparation methods are targeting improved strength and production efficiency with reduced Portland cement and embodied carbon. This technology will be used in the manufacture of concrete blocks, roof tiles and brick and block mortar products currently manufactured by Brickworks. Outcomes are efficient and sustainable full scale manufacture of higher value, low embodied carbon, lightweight, large format and/or high durability products that are not currently available to the Australian market.. Scheme: Mid-Career Industry Fellowships. Field: 4016 - Materials Engineering. Lead: A/Prof Yunfei Xi

Developing a recyclable carbon fibre composite capability for Australia. This project will use innovative surface modification techniques on reclaimed and virgin carbon fibres to enhance their compatibility with thermoplastic polymers. Valorising reclaimed carbon fibres and optimising thermoplastic composite materials will overcome the global industry challenges of: Raw material shortfall and High-volume manufacture, respectively. The successful implementation of this work will enable the critical role that high performance carbon fibre composite materials will play in transitioning to alternative energy sectors such as wind and hydrogen. This fellowship will create a sovereign capability and source of high value materials for Australia that will benefit energy, construction, mining, and defence.. Scheme: Mid-Career Industry Fellowships. Field: 4016 - Materials Engineering. Lead: Prof Luke Henderson

Unlocking the full reproductive potential for hybrid wheat breeding. Globally, wheat is cultivated as an inbred self-fertile crop with yield gains stagnating over the last decades. This contrasts with unabated yield gains and yield stability achieved for rice and corn through hybrid breeding and cross-pollination. Wheat hybrids hold potential for a 10-22% yield boost, but commercial deployment is restricted due to high seed production costs, a result of wheat’s floral architecture and poor outcrossing characteristics. This project aims to reduce costs by improving wheat’s female receptivity to airborne pollen, a major bottleneck to commercial realization of hybrids globally. Higher and more stable yields from wheat hybrids will ensure food security in the face of climate uncertainty and growing population.. Scheme: Mid-Career Industry Fellowships. Field: 3108 - Plant Biology. Lead: A/Prof Ryan Whitford

High-performance ammonia electrosynthesis devices. The project aims to develop a robust process for electrosynthesis of ammonia using devices manufactured by Melbourne company Jupiter Ionics P/L and innovative electrolyte components. Towards this aim, tailored ion-shuttling compounds need to be designed and investigated to enable continuous generation of ammonia in scaled-up flow devices. This is expected to generate new knowledge in practical electrochemistry, catalysis and sustainable synthesis. Key project outcome is a technology for production of ammonia from renewables that is pollution-free and highly scalable in contrast to the current process. Resulting benefit to Australian agriculture businesses is a method for distributed fertiliser generation without the use of fossil fuels.. Scheme: Early Career Industry Fellowships. Field: 3406 - Physical Chemistry. Lead: Dr Hoang-Long Du

Novel gestural technologies for musicians with physical disability. This project aims to address the under-representation of people with disability in the Australian music industry by developing innovative, accessible gestural instruments. Teaming up with key industry partner, YourDNA Creative Arts, an accessibler arts organisation, this interdisciplinary project expects to generate new knowledge in instrument design, inclusive technology and creative artificial intelligence. Using mixed-methodologies, expected outcomes include music and performance which is socially inclusive, economic participation, and the health and well-being of musicians with disability. This should provide significant benefits to Australian society by breaking down barriers that hinder their effective participation in society.. Scheme: Early Career Industry Fellowships. Field: 3603 - Music. Lead: Dr Alon Ilsar

A next generation 'smart' superconducting magnet system in persistent mode. Superconducting magnet devices use splicing, a process required to maintain the persistence of operation. Currently, the formation mechanism of splicing using magnesium diboride superconductor is complex and not technologically robust for industrial magnet manufacturing. This project aims to develop novel, reliable and economical superconducting splicing technologies that can produce an ultra-stable and uniform magnetic field against unexpected power outages. Expected outcomes include the development of advanced green and cryogen free superconducting technologies, which would boost the Australian manufacturing industry through access to multi-billion-dollar global markets for power grids, medical imaging and energy generation and storage.. Scheme: Linkage Projects. Field: 5104 - Condensed Matter Physics. Lead: A/Prof Md.Shahriar Hossain

Designer Nanoparticles Enable mRNA Protein Factories. Intracellular delivery of mRNA facilitates target protein production, which could build protein factories that are essential in biomanufacturing industries. However, the instability of mRNA greatly lowers the protein production performance, limiting the commercial translation potential. This project aims to develop a new generation of nanoparticle delivery system to enhance mRNA stability against intracellular unstable cue, enzymatic digestion and thermal stress. This will be achieved by tailoring the nanochemistry at multi-scales. Expected outcomes include new knowledge in custom-design of functional nanomaterials for mRNA delivery, and new technology that will bring commercial benefits to the partner organisation and the biopharma sector.. Scheme: Linkage Projects. Field: 4016 - Materials Engineering. Lead: Prof Chengzhong Yu

A miniaturised laser manipulator for ultra-precise and pain-free dentistry. This project aims to develop a miniaturized high-precision laser robotic device that can fit comfortably in the mouth to perform pain-free, vibration-free dental operations by utilising silicon-carbide on silicon technology to create a millimetre-sized two-axis controllable, highly-reflective mirror robust to high-power ultra-short laser pulses. This project expects to generate new knowledge in micro-mirror control using optically excited piezo-resistive sensors, and cold femtosecond laser ablation of hard dental tissue. Expected outcomes include a working prototype for laser removal of tooth materials at speeds exceeding dental drills, providing benefits in miniaturized laser devices and ultimately removing pain from dental procedures. . Scheme: Linkage Projects. Field: 4017 - Mechanical Engineering. Lead: Prof Dzung Dao

Upscaling genetic management of wildlife populations. Earth’s biodiversity is in crisis: many species are threatened with extinction and need our help. Genetic management helps to stop extinctions and promotes the health and continued existence of our wildlife. This project aims to understand how to use genome science to support preservation of four endangered species in changing climates and apply these learnings to help other species to survive and thrive. Anticipated outcomes include innovative approaches to aid conservation decision-making, automated analyses of genome data, and improved conservation training. The expected benefits include larger, healthier populations of four species, new ways of saving other species, and the provision of important resources for conservation managers.. Scheme: Linkage Projects. Field: 4104 - Environmental Management. Lead: Dr Alexandra Pavlova

Low-temperature ceramic electrolysis cells for renewable energy technology. This project aims to develop advanced protonic ceramic electrolysis cells for greatly improving the efficiency of hydrogen production and carbon dioxide conversion using renewable energy. This will be achieved by nanoscale integration of proton-conducting two-dimensional materials with solid acids and ceramic proton conductors to lower the manufacturing costs and operating temperature of protonic ceramic electrolysis cells. Expected outcomes of the project include new intellectual property on materials formulation and process parameters for commercial development of this new type of ceramic electrolysis cell, thereby contributing to the growth of Australian manufacturing and renewable energy industries and reduction of carbon emissions.. Scheme: Linkage Projects. Field: 4016 - Materials Engineering. Lead: Prof Huanting Wang

Building green roads with gasified municipal solid waste composites. This project aims to develop gasified municipal solid waste composites as a novel and green road material. This project expects to generate new knowledge on the fundamental properties of the developed waste composites when used as road subgrades and bases, through experimental study, physical modelling, numerical simulation, and field trials. Expected outcomes include understanding the mechanical behaviour of these waste composites under static and cyclic loads, development of versatile constitutive models and numerical analysis tools, and determination of their optimal performance. Benefits include diversion of municipal and demolition wastes from landfills and the development of sustainable materials and technology for future roads.. Scheme: Linkage Projects. Field: 4005 - Civil Engineering. Lead: Prof Arul Arulrajah

Boosting organ donation registration in diverse communities. This project aims to increase the number and diversity of people on the Australian Organ Donor Register. Transplant success can increase when organs are matched between people of similar ethnic backgrounds, but diverse communities have historically low registration rates. This project is significant because it focuses on this disparity to co-create with two diverse communities interactive media and community dissemination strategies that respect cultural and religious beliefs while addressing concerns about donation raised in our previous research. Tested with a third diverse community, the outcome will be a model that can be both scaled and tailored to ensure equitable access to transplantation for all, benefiting the lives of many. . Scheme: Linkage Projects. Field: 4206 - Public Health. Lead: A/Prof Gail Moloney

Highly efficient microscale liquid handling and bio interfacing. The aim is to establish the exciting new field of micro elastofluidics, enabling the development of a highly competitive, sovereign capability in Australia, utilising flexibility and stretchability for efficient and precise handling of tiny volumes of liquid. The program will fill a critical gap in fundamental knowledge in fluid-structure interactions, leading to the development of wearable and implantable devices. The expected outcomes include innovative platform technologies for sample storage, handling and unique device-human interfaces with broad applications in health and defence. Expected benefits include enhanced capabilities in medical diagnostics, defence force protection and Australia’s sovereign high-tech manufacturing.. Scheme: Australian Laureate Fellowships. Field: 4012 - Fluid Mechanics and Thermal Engineering. Lead: Prof Nam-Trung Nguyen

The cognitive neuroscience of motor skill learning. The capacity to produce skilled motor behaviour is essential for success in almost every aspect of our lives, whether it be playing sport, driving a car, operating machinery at work, or touch-typing. This project aims to establish the causal role of brain regions in motor skill learning by combining cutting-edge techniques in neuroimaging and brain stimulation. It is expected to lead to fundamental new knowledge on how new motor memories are created to enable the expression of skilled motor behaviour. The knowledge gained from this project may identify new strategies for learning skills that are widely applicable to education, industry, sport, and health.. Scheme: ARC Future Fellowships. Field: 5202 - Biological Psychology. Lead: A/Prof James Coxon

New perspectives on nonlocal equations. This project aims at tackling cutting-edge problems in the field of mathematical analysis, with specific focus on nonlocal equations, by introducing innovative approaches and a unified perspective. It focuses on the use of long-range interactions to deeply understand new effects arising in several mathematical problems of great impact. The research will be performed through stimulating international collaborations, providing exchange opportunities and ideal conditions for students to complete their training. The expected outcomes include new techniques to solve difficult problems, high impact international research collaborations, training of the next generation of mathematicians and top tier journal publications.. Scheme: ARC Future Fellowships. Field: 4904 - Pure Mathematics. Lead: Prof Serena Dipierro

Additive Manufacturing of Nanotwinned Titanium Alloys for Critical Use. The project aims to use 3D printing technology to create new titanium alloy components that are substantially lighter and stronger than current versions and therefore highly relevant for high temperature and stress uses in leading-edge industries such as aeroplane manufacture. The project expects to create new means to strengthen and improve the resilience of the commercial alloys’ microstructure with unprecedented in-service performance and thereby substantially broaden the industrial adoptions of 3D-printed products. This should also provide significant cost and environmental benefits and enhance Australia’s international standing in cutting-edge research on advanced manufacturing and materials.. Scheme: ARC Future Fellowships. Field: 4014 - Manufacturing Engineering. Lead: Dr Yuman Zhu

Innovations in Green Chemical Manufacture from Synchrotron based Techniques. This project aims to find sustainable ways to produce commodity chemicals by developing new catalysts. New synchrotron techniques will be developed and applied to provide new knowledge about the spatial and temporal factors affecting the selectivity and efficiency of electron transfer, redox reactions and diffusion, key for catalyst design. Expected outcomes include the development of new catalysts, new catalyst design concepts and a knowledge repository/database of analytical observations key for unlocking new materials knowledge. This should provide significant economic and environmental benefits by placing Australia at the forefront of the sustainable production of commodity chemicals.. Scheme: ARC Future Fellowships. Field: 3402 - Inorganic Chemistry. Lead: Prof Rosalie Hocking

From Snowball Earth to Animals: the Influence of Mantle Dynamics. This project aims to investigate how solid Earth processes contributed to ‘Snowball Earth’ events around 700 million years ago and to the explosion of complex life 540 million years ago, which will shed light on our origin as a species. The approach consists of merging cutting-edge models of the plate-mantle system with the global rock record. The intended outcome is to understand relationships between mantle convection, the behaviour of the magnetic field, global sea levels, continental-scale topography, and the composition of the ocean and atmosphere. Expected significant benefits include building capacity in Earth Sciences and the development of new models that can be used to explore the mineral endowment of the Australian crust.. Scheme: ARC Future Fellowships. Field: 3706 - Geophysics. Lead: A/Prof Nicolas Flament

ARC Training Centre for Development of Advanced Radiochemical Technologies. This project aims to train the next generation of radiochemists and discover new molecular approaches to harness radioactivity. Novel chemistry exploiting molecular incorporation of radioactive elements, stable chelation of metal radionuclides, bioconjugation methodologies, radioactivity capture via nanomaterials and cages, and the design of new peptidomimetic targeting molecules will deliver technological advances to radiopharmaceutical science. Outcomes will include a highly-skilled workforce and enhanced commercial capacity to meet a rapidly escalating global radiopharmaceutical market. This project will provide significant benefits by securing an internal supply chain and know-how for cutting-edge radiochemical technologies.. Scheme: Industrial Transformation Training Centres. Field: 3402 - Inorganic Chemistry. Lead: Prof Andrea Robinson

ARC Research Hub for Future Digital Manufacturing. This Hub aims to grow and accelerate Australian digital manufacturing (DM) transformation by devising novel DM technology and commercialisation/adoption pathways. The Hub expects to transform industry by developing novel AI and IoT-powered DM technology that provides for dramatic improvement in manufacturing productivity, resilience and competitiveness. Expected outcomes include novel DM technology for digitally representing, predicting, and improving production and its outcomes via an open platform that supports reusing industry co-created DM solutions. Through supporting advanced manufacturing priorities and Industry 4.0, the Hub should provide significant benefits by increasing Australian manufacturing productivity and resilience by 30%.. Scheme: Industrial Transformation Research Hubs. Field: 4606 - Distributed Computing and Systems Software. Lead: Prof Dimitrios Georgakopoulos

ARC Training Centre for Radiation Innovation. This Centre aims to train the next generation of transdisciplinary leaders to enable, grow and transform industries that utilise or are impacted by radiation. Rapid growth in the natural resources, health, space and national security sectors urgently requires a highly capable workforce with scientific and regulatory knowledge to develop new technologies and social licence needs to maximise benefits. Outcomes include new methods of radiopharmaceutical production, more resilient spacecraft and robust regulatory frameworks. Industries and communities will benefit from a future workforce prepared for safe adoption, development and delivery of emerging techniques and advanced radiation technologies, enhancing Australia’s prosperity and security.. Scheme: Industrial Transformation Training Centres. Field: 5106 - Nuclear and Plasma Physics. Lead: Prof Mahananda Dasgupta