Grants & Opportunities

Improving grain legume seeds for future climates. Grain legumes are essential for sustainable agriculture and human dietary protein, but seed quality is predicted to decline under future scenarios of high CO2 and warmer temperatures. This project aims to improve legume seed quality under future climates by comparing metabolites and physiological traits of chickpea and other legumes to establish mechanisms by which legumes maximise seed nutrient allocation. The anticipated outcomes include new metabolite-based breeding markers for the improvement of crops with higher seed proteins, micronutrients and bioactive compounds that are adapted to future climates. Seed nutrient improvement will also include increased biological nitrogen fixation to reduce the need for chemical nitrogen fertilisers.. Scheme: Discovery Projects. Field: 3108 - Plant Biology. Lead: Prof Ulrike Mathesius

Optimisation of Buildable Structures for 3D Concrete Printing. This project aims to establish a systematic approach to seamlessly integrate optimisation, characterisation, and 3D concrete printing (3DCP) manufacturing for the construction and building industry. New optimisation algorithms will first overcome the manufacturing limitations of 3DCP by considering the print path and early-age concrete properties, and directly create high-performance and innovative designs of buildable structures. The outcomes of this project include a powerful design tool that enables architects and engineers to optimally design and construct the next generation of cost-saving and aesthetically pleasing buildings and infrastructures through the adoption of modern 3DCP technology.. Scheme: Discovery Projects. Field: 4017 - Mechanical Engineering. Lead: Prof Xiaodong Huang

Beyond Query: Exploratory Subgraph Discovery and Search System. Exploring co-working user groups in dynamic network data is a vital challenge in many applications, for example, in online education. This project aims to discover new relationships of users and compute their co-working performance in continuous time periods. The outcomes of the project are to design effective subgraph exploratory models, three novel types of subgraph search solutions, and devise a friendly exploratory subgraph search system for supporting the real-time network data analytics. The success of the project will make a significant contribution to the scientific foundation of graph data mining and its applications in data engineering domains, as well as benefiting co-working performance of people in Australian labor markets.. Scheme: Discovery Projects. Field: 4605 - Data Management and Data Science. Lead: Prof Jianxin Li

Big time crystals: a new paradigm in condensed matter. This project aims to extend condensed matter physics to the time dimension using big time crystals created by a periodically driven Bose-Einstein condensate. Such a system is expected to offer exceptional versatility, allowing effective potentials and long-range interactions in a time lattice to be engineered almost at will by proper periodic driving and modulation of the particle interaction. Expected outcomes include realisation of novel condensed matter phenomena such as topologically protected states in the time dimension, time crystalline structures exhibiting disorder or quasi-crystalline order and time-tronics devices analogous to electronics. Potential future benefits include novel advanced materials and semiconductor-like devices. . Scheme: Discovery Projects. Field: 5108 - Quantum Physics. Lead: Prof Peter Hannaford

Addressing significant product safety knowledge gaps for older Australians . This project addresses significant gaps in contemporary knowledge of consumer product safety risks for older persons, with 25 years since the last Australian product safety research found older persons are at high risk of product-related injury/death. Products have evolved substantially and aged care models have changed in that time. This project generates contemporary knowledge of unsafe products causing injuries/deaths, risk factors/behaviours, and human rights issues. Outcomes benefiting the Australian community are improved prediction/characterisation of product safety issues for older Australians informing safer product design and use, targetted regulatory responses, ageing-in-place strategies, and creating safer home environments.. Scheme: Discovery Projects. Field: 4203 - Health Services and Systems. Lead: Prof Kirsten Vallmuur

Exploiting James Webb Space Telescope Observations of the First Galaxies. This Discovery Project aims exploit the next generation spectroscopy with the James Webb Space Telescope, combined with Australian supercomputing expertise to make fundamental new measurements of the formation of stars in the first galaxies. The results will be used to make predictions for key experiments that will be conducted with the Square Kilometer Array. The research outcomes aim to benefit astronomy by generating new knowledge of high redshift galaxies and provide new spectral star-formation diagnostics which will be made available to the general astronomical community. The project also aims to provide cultural benefit through effective public and education as well training of future leaders for astronomy and industry research.. Scheme: Discovery Projects. Field: 5101 - Astronomical Sciences. Lead: Dr Kathryn Grasha

Human models for accelerated robot learning and human-robot interaction. This project aims to develop novel approaches to teach robots to proficiently interact with humans in a safe and low-cost manner. To achieve this aim, this project will develop novel models from which various human behaviours can be generated and used to train human-robot interaction policies in simulation. Expected outcomes of this project include new computational models of human behaviour built using cognitive science theories and limited data and new training schemes for robot learning in simulation. By training robots in simulation with accurate human models, this research will enable fast and safe robot training to support the deployment and adoption of robots in human contexts such as healthcare facilities, homes, and workplaces.. Scheme: Discovery Projects. Field: 4602 - Artificial Intelligence. Lead: Prof Dana Kulic

Australian Journalism, Trauma and Community. This project aims to investigate the professional and personal costs of reporting on trauma for Australian journalists and the communities they engage with, by undertaking a groundbreaking historical study of journalists’ exposure to trauma over the past century. It seeks to generate new knowledge by transforming our understanding of the relationship between journalism and trauma and the wider implications for the profession and the public. Expected outcomes of this project include scholarly, education and public resources which will inform and broaden ongoing debates about Australian journalism. This will provide significant benefits for journalists and the public, creating urgent awareness and better support and training initiatives. . Scheme: Discovery Projects. Field: 4303 - Historical Studies. Lead: A/Prof Fay Anderson

An in-built depolymerisation solution for polyethylene waste. This project aims to design enzymes that can be embedded into polyethylene, and later activated by the elevated temperatures of a compost heap, to depolymerise the plastic to small molecules. There are no good options available for the controlled decomposition of polyethylene waste at present, and instead researchers have focussed on solutions that rely on modifications to the underlying chemistry of the backbone and or collection to a central facility. Our approach would result in an in-built decomposition that does not require collection and recycling in a central facility. Since it is based on a depolymerisation mechanism it does not result in the production of harmful, partially disintegrated microplastics.. Scheme: Discovery Projects. Field: 3403 - Macromolecular and Materials Chemistry. Lead: Dr Robert Chapman

Open(ing up) goals in physical activity: What works, when, and for whom? This project aims to advance knowledge of open goals as a new goal-setting approach to optimise the adoption and maintenance of physical activity among insufficiently active individuals. This project expects to generate substantive insights into the mechanisms that explain why, when, and for whom open goals are particularly beneficial in this population. Expected outcomes include a theory of open goals that will inform physical activity promotion efforts, with the potential for broad population-level dissemination and scale-up. Significant benefits include the ability to set physical activity goals that are enjoyable and intrinsically motivating to pursue, while also avoiding detrimental effects of current practice (eg high failure rates).. Scheme: Discovery Projects. Field: 5201 - Applied and Developmental Psychology. Lead: Prof Christian Swann

Resilient Remote Environment Emulation for Human-to-Machine Communication. Human-to-machine haptic communication allow humans to immersively interact with remotely-located robots/machines. Current networks cannot support its technical demands, thereby limiting the achievable human-machine distance. This project aims to develop cloudlet intelligence together with a programmable resilient network to realise reliable remote environment emulation, a concept where the physical environment at the remote machine is emulated close to the human. A key outcome will be the first reliable remote environment emulation platform that achieves vast human-machine distances on current networks. Enabling immersive human-machine experience will significantly benefit many sectors, from education through to industrial manufacturing.. Scheme: Discovery Projects. Field: 4006 - Communications Engineering. Lead: Prof Elaine Wong

The mobilome of the anaerobic methanotrophic archaea Methanoperedenaceae. Microorganisms play a critical role in regulating Earth’s climate, but how they are affected by our rapidly changing environment is not well understood. This Discovery project will study a group of microorganisms found in freshwater sediment that can consume the potent greenhouse gas methane before it is released into the atmosphere. We have developed new methods to investigate how genetic material is exchanged between microorganisms, and how this helps them adapt to environmental changes. Together, this will ultimately help us develop better climate change prediction models and contribute to our understanding of microbial communities that are crucial for environmental health.. Scheme: Discovery Projects. Field: 3107 - Microbiology. Lead: A/Prof Simon McIlroy

Advancing Child and Youth-led Climate Change Education with Country. Climate change education is in its infancy. By co-researching with Indigenous and non-Indigenous children, youth, and Elders across Australia and Canada, this project conceptualises and advances climate change education with Country. Climate change education is not adequately understood within Western science. Western perspectives on climate crises are in deep contrast to Indigenous perspectives enmeshed in continuous storying with descendants, ancestors, and Country. Collaborating with Elders, this project will generate child and youth-led transcultural curriculum and pedagogical understandings of climate change education with Country. It delivers on the United Nations Convention on Climate Change through corresponding quality education.. Scheme: Discovery Projects. Field: 3901 - Curriculum and Pedagogy. Lead: Prof Amy Cutter-Mackenzie-Knowles

The role of protein glycosylation in erythropoiesis . This project aims to understand how the sugar code of key-signalling proteins influences the development of red blood cells. This project expects to generate new fundamental knowledge in the area of stem cell signalling by innovative integration of biological and computational molecular characterisation techniques. The expected outcomes of this project include the development of novel workflows to study key regulators of cell development and the generation of new knowledge in stem cell signalling that will find applications in transforming stem cell therapies and associated research for future applications such as the laboratory manufacturing of red blood cells to close the availability gap for transfusion purposes.. Scheme: Discovery Projects. Field: 3101 - Biochemistry and Cell Biology. Lead: Prof Daniel Kolarich

Decoding microtubule remodelling in sperm production. All eukaryotic cells possess a dynamic microtubule (MT) cytoskeleton, which requires constant remodelling to satisfy its many essential cellular roles. Emerging data suggests modifications to the MT surface (the tubulin code) may act as instructional signposts for remodelling. This project aims to define a fundamental component of the tubulin code, glutamylation, and define how this directs MT severing. It also aims to define the cellular functions of MT-severing enzyme FIGNL1 and key MT glutamylation enzymes (CCP1, CCP5 and TTLL1). Insights will be generated using sperm production as a model system and will thus inform the mechanisms by which fertile sperm are built, in addition to being relevant to cell biology across eukaryotic species. . Scheme: Discovery Projects. Field: 3215 - Reproductive Medicine. Lead: Prof Moira O'Bryan

Using Conservation Covenants for Ecosystem Restoration & Climate Adaptation. This project aims to investigate the role of conservation covenants in facilitating ecological restoration and adaptation to climate change. In light of international experience, the project examines Australia's legal experience with conservation covenants, with case studies in NSW, Queensland, Tasmania and Victoria. The project expects to generate new theoretical insights and practical knowledge about the obstacles and opportunities for enabling covenants to play a more ambitious role in meeting biodiversity conservation and recovery goals. This should generate significant benefits to Australia in meeting its international environmental obligations, and improving collaboration between governments and community and landholder stakeholders.. Scheme: Discovery Projects. Field: 4802 - Environmental and Resources Law. Lead: Prof Benjamin Richardson

Cultivating digital music making in regional Australia. The project aims to examine effective methods of aligning local infrastructure and online resources to support digital music creators and their communities in regional Australia. It will promote digital creative industries and augment existing investments in regional art institutions and digital fabrication infrastructure. The project collaborates with regional digital artists to share their skills and expertise, with the goal of improving coordination of resources and infrastructure for the growth of regional digital creatives and engagement with their communities. Knowledge outcomes will assist governments in optimising the delivery of creative services and resources in regional Australia. . Scheme: Discovery Projects. Field: 4410 - Sociology. Lead: Prof Andrew Bennett

Polarons in flatland. This project aims to generate new theories of excitons (the solid-state analogue of hydrogen atoms) in charge-doped atomically thin semiconductors. Such theories are urgently needed to describe the response to external probes, such as electric fields, of a range of novel materials that have emerged in recent years. The novelty is to treat the behaviour of semiconductors as a quantum impurity problem, where the excitons become modified by the surrounding electrons to form new types of particles. A greater understanding of the impurity problem in 2D materials would ultimately facilitate their use in emerging technologies that combine electronics with photonics, for use in ultra-low-power devices such as photodectectors, LEDs, and lasers.. Scheme: Discovery Projects. Field: 5108 - Quantum Physics. Lead: A/Prof Jesper Levinsen

Southern Ocean aerosols: sources, sinks and impact on cloud properties. This project aims to provide fundamental process-level understanding of atmospheric aerosol processes over the Southern Ocean, a region that has a profound influence on the Australian and global climate and where climate models perform poorly. Comprehensive observations during 3 Southern Ocean voyages and land-based measurements will enhance our knowledge of aerosols and cloud formation in that region and provide much-needed data for improving global climate models. Expected outcomes include more accurate seasonal and latitudinal representations of Southern Ocean aerosol populations, properties and sources. The main benefit includes improvements in weather forecasting and future climate projection for Australia and the Southern Hemisphere.. Scheme: Discovery Projects. Field: 3701 - Atmospheric Sciences. Lead: A/Prof Branka Miljevic

Making Strongly Interacting Photons. This theoretical project aims to investigate strongly correlated polaritons in quantum physics. Known as quantum fluids of light, polaritons are half-light, half-matter particles exhibiting frictionless, zero-energy-cost flows, an astonishing quantum behaviour known as superfluidity. This project expects to make a breakthrough in our understanding of polaritons in the strongly interacting regime far from equilibrium and fill in the knowledge gap towards the realisation of a superfluid of light at room temperature. This should open a new era of quantum polaritonics that forms the basis for energy-efficient laser and all-optical transistor, establishing Australia as a world leader in commercialising novel photonic technologies.. Scheme: Discovery Projects. Field: 5108 - Quantum Physics. Lead: Prof Xia-Ji Liu

The Global Structure of Sparse Networks. Graph theory (the mathematics of networks) models many real-world problems and is a major area of modern mathematics. This project aims to investigate the global structure of graphs using product structure theory, which is a recent breakthrough method that has been the key to solving several open problems. The goal is to extend the reach of product structure theory and to discover new fields of application, especially in theoretical computer science. It is expected that the tools developed will be widely applicable, for example, in network optimisation. The project aims to build collaborations between Australian researchers and world-leading international mathematicians, and provide advanced training for talented young researchers.. Scheme: Discovery Projects. Field: 4904 - Pure Mathematics. Lead: Prof David Wood

Braiding Dynamics of Majorana Modes. The project aims to investigate Majorana modes, exotic quantum particles which can be found in the new material class of Topological Superconductivity. In particular, they can be utilised to construct fault-tolerant quantum bits. Quantum logic gates are enabled by moving these Majorana modes around each other, i.e., by braiding them, leading to an error-free quantum performance. This project will deliver cutting-edge simulations to analyse the braiding process in condensed matter systems and benchmark how these fault-tolerant quantum bits operate under real-world conditions. By providing the theory for advanced structures and devices, this project will inform experiments and pave the way for future technology based on topological phenomena.. Scheme: Discovery Projects. Field: 5104 - Condensed Matter Physics. Lead: Prof Dr Stephan Rachel

Analysing and disrupting outlaw motorcycle gangs in Australia. This project aims to reveal the structure and social dynamics of co-offending networks by OMCGs in Australia. Outlaw motorcycle gangs (OMCGs) cause significant social and economic harm in Australia and internationally. The project will generate new knowledge about OMCG co-offending using an innovative multimethod approach combining social network analysis with interviews and focus groups. Expected outcomes include a deeper understanding of OMCG criminal activity across Australia and refined theory development about co-offending in criminal groups. The project will lead to improved policy, legislation and policing practice to prevent OMCG crime and dismantle OMCG criminal networks in more cost-effective ways.. Scheme: Discovery Projects. Field: 4402 - Criminology. Lead: Prof David Bright

Unlocking the secret chemistry of organosulfur biodegradation. The element sulfur is essential for life. Its transformation between organic-sulfur compounds to inorganic forms is a crucial part of the biogeochemical cycle. This project will elucidate the molecular details of the final leg of the biosulfur cycle: organosulfur breakdown into mineral form. An integrated chemical and biochemical approach will be used to illuminate how the carbon-sulfur bond is broken. This project will deliver a detailed molecular understanding of organosulfur breakdown to permit organosulfur recycling. Benefits of this research include potential biotechnology applications for breaking down xenobiotic organosulfonates and sustainable approaches to reduce dependence on agricultural fertilisers.. Scheme: Discovery Projects. Field: 3404 - Medicinal and Biomolecular Chemistry. Lead: Prof Spencer Williams

A femtosecond beamline for time-resolved momentum microscopy. This project aims to obtain a femtosecond high-harmonic generation beamline that will be integrated with a photoemission electron microscope to create Australia’s first time-resolved momentum microscope. This project expects to use ultrafast spectromicroscopy to observe the changes to the excited electron motion within materials after they absorb light. Expected outcomes of this project include improving our understanding of light-driven physical and chemical processes that occur in materials and optoelectronic devices. This should provide significant benefits through the development of new cost effective and efficient materials for energy harvesting, sensors and photocatalysts.. Scheme: Linkage Infrastructure, Equipment and Facilities. Field: 5104 - Condensed Matter Physics. Lead: Dr Darryl Jones