Grants & Opportunities

Mapping & Harnessing Public Mistrust: Constitutional Values Survey 2023-27. Declining public trust is well recognised as a problem of democratic government, including in Australia. However solutions are more elusive, confounded by the reality that mistrust and distrust play not just negative, but positive roles in our existing political and constitutional traditions. This project aims to be the first to comprehensively map the positive values of mistrust in citizen political attitudes and experience, building on previous Constitutional Values Surveys (2008-21) to test new measures of the content of trust including a first-ever longitudinal study of changing trust over time. The results will inform concrete solutions to three key policy reform dilemmas, providing better answers for sustaining public trust overall. . Scheme: Discovery Projects. Field: 4408 - Political Science. Lead: Prof Alexander Brown

Veteran suicide: investigating the historical and social dimensions . This project aims to address veteran suicide by conducting an historical and cultural analysis of the ways government, the military and the community have understood, governed, and serviced veterans from 1914-present. This project will generate new knowledge, moving beyond orthodox medical and cultural assessments to explore wider historical, cultural and sociological relations of veteran suicide, including civil military relations, and the influence of the veteran sector and families and community. The project will develop an innovative survey that will form the foundation of a longitudinal social health and wellbeing dataset on veterans, and contribute to policy and service provision to reduce veteran suicide and improve their wellbeing.. Scheme: Discovery Projects. Field: 4410 - Sociology. Lead: Prof Ben Wadham

Innovative Stable Free Radical-Substituted Conjugated Electronic Polymers. The project aims to develop an innovative class of stable free radicals side-chain substituted conjugated donor-acceptor electronic polymers with unique polaronic and radical charge transport capabilities. The targeted optoelectronic material class is unique and has not been explored in depth before. The combination of unpaired electrons and delocalized backbone -electrons delivers exciting modes of charge transfer that provide these novel materials with clear potential as electroactive materials with applications in various nanoelectronics devices. Developing a fundamental understanding of charge transport properties and potential device applications will open up a new field of research in advanced optoelectronic technology. . Scheme: Discovery Projects. Field: 4016 - Materials Engineering. Lead: Prof Prashant Sonar

Dynamic Microcages for Cells: Advanced Tools to Interrogate Cell Mechanics. This project aims to develop a suite of movable micro/nanostructures with integrated mechanical and biological sensors, which will be interfaced with cells to investigate how those cells respond to their surrounding physical environment. Expected outcomes are new technologies in micro/nanofabrication, sensing, and advanced imaging, and deep understanding of the biological processes that control tissue formation and repair. These outcomes would impact how 3D microsystems are developed and applied, informing the design of advanced in-vitro cell culture systems. Significant benefits are expected in 3D nano-microengineering, and in generating new knowledge underpinning future advances in stem cell and tissue engineering technologies.. Scheme: Discovery Projects. Field: 4018 - Nanotechnology. Lead: Prof Nicolas Voelcker

A platform technology for developing mesoporous polymer particles. This project aims to apply polymerisation-induced self-assembly process to develop triggerable mesoporous polymer particles as advanced functional materials for various applications. By combining this scalable process and automated synthesis technique, mesoporous polymer particles that can disassemble in response to external triggers, such as light, redox conditions and enzymes, will be developed. The knowledge gained from this research will allow researchers to fully understand the formation and evolution mechanism of inverse bicontinuous structures observed in nature and produced in synthetic labs. Importantly, the applications of these novel stimuli-responsive particles as nano-carriers and templating scaffolds will be investigated.. Scheme: Discovery Projects. Field: 3403 - Macromolecular and Materials Chemistry. Lead: Prof San Thang

Political Representation in Indonesia. The project aims to understand political representation in Indonesia, asking how far politicians resemble voters in both their policy views and backgrounds (gender, religion, education etc.) It will generate new knowledge on a major potential source of fragility in the world’s third largest democracy, and pioneer a new multi-method approach for explaining how representation varies. Expected outcomes include a new framework that extends analysis of representation to illiberal democracies, and a tranche of public data on Indonesia for cross-national comparisons. Benefits will include a new set of analytical tools to help policy makers in Australia and the region assess sources of weakness in representative institutions in illiberal settings.. Scheme: Discovery Projects. Field: 4408 - Political Science. Lead: Prof Edward Aspinall

The Benefits of Utilising Visual-Spatial Representations of Numbers . The aim of this project is to investigate how visual-spatial representations of numbers enhance practice to promote the use of retrieval-based over counting-based strategies for children learning early arithmetic. About one-third of Australian children stay reliant on counting strategies for basic arithmetic, despite these being associated with lower achievement in mathematics in later years. Expected outcomes of this project are new understandings of how problem-answer associations can be strengthened in memory and the development of tools to promote retrieval-based strategies. Potential benefits include children who are better prepared to take on higher-level mathematics in secondary school and, subsequently, more numerate citizens. . Scheme: Discovery Projects. Field: 3904 - Specialist Studies In Education. Lead: A/Prof Sarah Hopkins

Understanding bone structure evolution using machine learning. Bone remodeling is the ancient process of bone resorption and formation that optimises material properties and has led to evolution of terrestrial vertebrates. To date it is not understood how remodeling achieves tuning of bone material. This proposal aims to develop a machine learning based approach, linking computational modeling and imaging to address this problem. Intended outcomes are development of a multiscale model of remodeling and machine learning algorithms for image analysis. This approach will help establish a structural-functional link between remodeling and bone material optimisation which ultimately provides significant benefits for bone tissue engineering, fracture healing and improved therapies for osteoporosis. . Scheme: Discovery Projects. Field: 4003 - Biomedical Engineering. Lead: Prof Peter Pivonka

Building A Better Built Environment for Older Australian's Ageing-in-place. Most older Australians prefer to age in place after their retirement. This project aims to understand how the built environment as a comprehensive system supports (or hinders) their ageing-in-place given that the existing Australian built environment fails to meet older Australians' requirements for independent living. This project expects to generate new knowledge in the area of ageing-friendly communities using Bayesian Network analysis and interactive design charrettes. Expected outcomes include an evidence-based Bayesian network model that determines how the built environment affects independent living in the community and design innovation and guidelines to improve the built environment design for older Australians' ageing-in-place.. Scheme: Discovery Projects. Field: 3302 - Building. Lead: Prof Bo Xia

Exploiting Geometries of Learning for Fast, Adaptive and Robust AI. This project aims to uniquely exploit geometric manifolds in deep learning to advance the frontier of Artificial Intelligence (AI) research and applications in cybersecurity and general cognitive tasks. It expects to develop new theories, algorithms, tools, and technologies for machine learning systems that are fast, adaptive, lifelong and robust, even with limited supervision. Expected outcomes will enhance Australia's capability and competitiveness in AI, and deliver robust and trustworthy learning technology. The project should provide significant benefits not only in advancing scientific and translational knowledge but also in accelerating AI innovations, safeguarding cyberspace, and reducing the burden on defence expenses in Australia.. Scheme: Discovery Projects. Field: 4611 - Machine Learning. Lead: Prof Dinh Phung

Global integration of microbial community and climate data. Microbial communities in the environment control the cycling of carbon and nutrients on Earth, but climate models do not directly incorporate microbial inputs. This interdisciplinary project will link planetary-scale climate modelling data with novel large-scale microbial community analysis, using climate information to provide insight into the fantastic diversity of microbial processes on our planet. The interdisciplinary approach will inform the next generation of climate models and better predict our future climate’s feedbacks. Conversely, it will make progress on the grand challenge of understanding microbial community function by enabling microbial ecology to be treated as a data-intensive machine learning problem.. Scheme: Discovery Projects. Field: 3107 - Microbiology. Lead: A/Prof Benjamin Woodcroft

The first English speakers in their own words. This project aims to produce the first comprehensive study of the attitudes in the earliest English literature. The project expects to generate new knowledge about the first English speakers, what issues mattered most to them and how broad the range of attitudes was. Expected outcomes of this project include new approaches to studying the past, enhanced international collaborations and a public access to the project's data through an open access digital resource. This should provide significant benefits in terms of our understanding of the past and how it shapes attitudes in contemporary Australia. . Scheme: Discovery Projects. Field: 4705 - Literary Studies. Lead: A/Prof Erin Sebo

Tackling Crystal Methamphetamine Supply in Rural and Regional Australia. This project tackles one of the leading drug policy and organised crime issues in Australia, namely the increased availability of crystal methamphetamine (ice) in rural and regional communities. The first study of its kind nationally, it will use an innovative combination of qualitative and quantitative methods across six communities in three states to uncover how ice infiltrates regional communities, the drivers and mechanisms and impacts thereof. Expected outcomes include a roadmap to reduce supply and harms, strengthened communities and enhanced international collaborations. With ice use and supply costing the Australian government $5 billion per year, the project stands to provide significant social, public health and economic benefits.. Scheme: Discovery Projects. Field: 4402 - Criminology. Lead: A/Prof Caitlin Hughes

Ultra-Fast and Secure Terahertz Communications for 6G Wireless Systems. This project aims to develop new theories and signal processing solutions for the cutting-edge technology of terahertz communications to enable the revolutionary sixth-generation wireless systems, by exploring and optimising the inherent benefits of the terahertz band. Anticipated outcomes are new analytical tools and practical guidelines for designing ultra-fast and secure wireless transmission at an unprecedented speed up to terabits per second (Tbps). This enables various emerging applications, such as holographic telepresence, Tbps WiFi and Tbps wireless data centres, to drive transformation in the telecommunications sector, boost industry productivity and support our intelligent information society in the 2030s.. Scheme: Discovery Projects. Field: 4006 - Communications Engineering. Lead: Prof Nan Yang

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

Every Day Matters: Reducing School Non-Attendance in Autistic Students. Autistic children miss one day a week of school, three times more than their peers. This significantly impacts their learning, wellbeing and later, their vocational outcomes. This project aims to identify the factors that put autistic children at increased risk of missing school and map the supports and interventions used to reduce school non-attendance. Expected outcomes include an autism-specific model of the how and why school non-attendance is elevated for autistic students. It is anticipated that this model make the important step of enabling teachers and professionals to identify which autistic children are most at risk of absenteeism and select the best strategies to support a positive and beneficial return to school.. Scheme: Discovery Projects. Field: 3904 - Specialist Studies In Education. Lead: Prof Dawn Adams

Determining the links between size and function in phytoplankton. Marine phytoplankton are responsible for around 50% of the carbon fixation on planet. This project will examine how phytoplankton size declines will alter marine food webs and carbon sequestration. Changes in nutrients and temperature will cause phytoplankton to be smaller but the consequences of these changes are uncertain because of a lack of knowledge regarding how changes in cell size affect function within a species. This project will evolve 20 species of algae to be different sizes and estimate the consequences of these size changes for biological functions. The project will then use these data to refine global models of carbon budgets, leading to better predictions about how the global carbon pump will change. . Scheme: Discovery Projects. Field: 3104 - Evolutionary Biology. Lead: Prof Dustin Marshall

Roads to the Future: Infrastructure and the New Development in Africa. This project aims to conduct a comparative analysis of new road schemes in East Africa and the Western Indian Ocean (a region which sits at the intersection of several major global transport and development corridors), in order to understand their economic, socio-political, cultural and public health effects. As global road-building accelerates at an unprecedented rate, especially in the developing world, there is an urgent need for new models for understanding roads' potential economic benefits, as well as their risks, including their environmental risks. This project is benefitting citizens, NGOs, donors and governments, by generating new knowledge about how we have in the past, do at present, and should in the future, engage with roads.. Scheme: Discovery Projects. Field: 4404 - Development Studies. Lead: Prof Richard Vokes

Gas-enriched slippery surfaces. This project will exploit novel experimental and simulations approaches to investigate gas enrichment at liquid-liquid interfaces, and its effect on interfacial slip. The outcomes of the project will be a deeper understanding of oil-water interfaces capturing the presence of interfacial gas layers, slippery surfaces with superior drag reducing and fouling reducing properties, and control over nanobubble formation under flow. The new surfaces will have potential application in improving the energy efficiency of microfluidic and multiphase flow. Benefits are expected in terms of reduced emissions, fuel cost and pollution related to transport of goods by sea, and extraction of oil from rocks.. Scheme: Discovery Projects. Field: 3406 - Physical Chemistry. Lead: Prof Chiara Neto

Diamane: A New Frontier in Materials Science. Single-layer diamond (‘diamane’) is a new frontier of material research although its preparation is still in infancy with many structures predicted possible but have not been made experimentally. Built on a new chemical route for 'graphite to diamane' transformation, this project will address a research gap towards synthesising new diamane(-like) nanostructures and developing an in-depth understanding of the chemically induced phase transformation and structure-property correlations, which will have far-reaching impact on scientific fields beyond carbon research. Preliminary data points to both feasibility and impact for discovering new materials and technologies, which will bring foreseeable scholarly, economic, and social benefits.. Scheme: Discovery Projects. Field: 4018 - Nanotechnology. Lead: Dr Sam Chen

Microspheres from (Sun)Light – A Sustainable Materials Platform. This project will break new ground in light-induced step-growth precipitation polymerisation techniques for polymer particle formation that do not require any initiator, surfactants, additives or heating, thus constituting an environmentally friendly process. The project will establish the underpinning photochemical particle formation processes and establish a broad monomer base for the production of particles with a wide property profile, including particles with tailored surface properties and the ability to degrade upon a defined trigger signal. Scaling the particles' synthesis, including using Australian sunlight, will enable multi-gram production allowing real-world applications.. Scheme: Discovery Projects. Field: 3403 - Macromolecular and Materials Chemistry. Lead: Prof Christopher Barner-Kowollik

Dispersing myths; Characterising human migration through Asia . The human journey across the globe is one of our greatest achievements, yet the archaeological evidence for the earliest migrations is poorly dated, plagued by uncertainty and often overlooked. This project aims to characterise the nature of early human dispersals across Asia en route to Australasia by going beyond the timing and identification of human evidence to explore their behaviour, health and adaptability. Reconsidering early migrations within their environmental context will allow an assessment of their feasibility and address the disparity between the genetic and physical evidence. By elucidating the story of the greatest human journey we will develop a new understanding and appreciation of our survival and adaption capabilities.. Scheme: Discovery Projects. Field: 4301 - Archaeology. Lead: A/Prof Kira Westaway

Resonant tender X-ray scattering of organic semiconductors. This project aims to establish resonant tender X-ray scattering as a mature technique for unravelling the complex microstructure of organic semiconductor layers. By understanding and exploiting the resonant interaction between organic semiconductors and X-rays tuned to appropriate absorption edges, new information about the molecular packing of these materials will be obtained. The expected outcomes are new experimental methodologies and analysis tools for determining the complex structure of technologically relevant materials. Benefits include understanding of the properties of solution-processed semiconductors enabling the design of high performance materials with applications in energy, electronics, lighting and health.. Scheme: Discovery Projects. Field: 5110 - Synchrotrons and Accelerators. Lead: Prof Christopher McNeill

Carbon in a Bubble: Cavitation in Ionic Liquids. This project aims to investigate the potential of pressure-driven phase change as an energy-efficient mechanism for removing dissolved gases from low melting point salts, by advancing understanding of the cavitation behaviour of ionic liquids. This project expects to generate new knowledge in the area of fluid mechanics through an innovative combination of advanced computational simulations and synchrotron X-ray measurement techniques developed by the investigators. Expected outcomes of this project include expanded understanding of the physics of ionic liquids, and the ability to engineer more efficient gas separation systems. The project aims to benefit the chemical and energy sectors through improved energy efficiency.. Scheme: Discovery Projects. Field: 4012 - Fluid Mechanics and Thermal Engineering. Lead: Dr Daniel Duke

Teacher attraction and retention in hard-to-staff schools. Australia is facing a teacher shortage crisis. Many schools have become ‘hard-to-staff’ – evident through either a lack of teachers or a high teacher turnover. The aim of this project is to provide the foundations for strategies that can be implemented by schools and systems to address this problem. Due to the schools’ locations, these shortages can have severe consequences for already educationally vulnerable young people. This has been a significant concern of governments nationally and internationally. An important outcome from the project will be how best to attract and retain teachers in hard-to-staff schools. This will have benefits for the teaching profession, young people who attend hard-to-staff schools and the broader community. . Scheme: Discovery Projects. Field: 3902 - Education Policy, Sociology and Philosophy. Lead: Prof Martin Mills