Grants & Opportunities

Effective integration of human and automated analyses for security testing. This DECRA project aims to significantly improve the performance of current state-of-the-art automated security testing approaches, enabling them to discover more security bugs in strict time constraints. The key innovation of the project is its novel way to embrace human element to leverage the ingenuity of the developers. This project will help companies improve the security and reliability of their products, thwarting cyberattacks that cost Australian business $29 billion each year. The knowledge from this project will be transferred and integrated into higher education subjects to train the next generations of software developers, who are responsible to build security-critical systems that we all rely on now and in the future.. Scheme: Discovery Early Career Researcher Award. Field: 4612 - Software Engineering. Lead: Dr Van Thuan Pham

Establishing a national program to characterise indoor chemical exposures. This project aims to establish the first Australian indoor air monitoring program that identifies hazardous chemicals and their sources and trends under a changing climate. The project expects to provide key evidence to policy-making decisions including prioritising indoor chemical threats for regulation. The expected outcomes include the establishment of criteria for home recruitment for indoor pollution research, identification of new chemical pollutants and their sources, and assessment of their trends. The benefit is to advance the knowledge on indoor exposure research, raise the awareness of the climate change conditions, addressing the government priority research area of Environmental Change.. Scheme: Discovery Early Career Researcher Award. Field: 4104 - Environmental Management. Lead: Dr Xianyu Wang

New Foundations for Algebraic Geometry. Differential calculus is one of the most important and widely applied areas of mathematics. Differential categories are a modern foundational theory of differential calculus with applications throughout mathematics and computing. This project aims to use differential categories to create new foundations for algebraic geometry, and to generate new knowledge on the connection between algebraic and differential geometry. The generality of these foundations will allow for novel applications of algebraic geometry with significant benefits to computer science, such as in machine learning and differentiable programming. We expect this to build Australia's profile in these important fields and help train the next generation of mathematicians.. Scheme: Discovery Early Career Researcher Award. Field: 4904 - Pure Mathematics. Lead: Dr Jean-Simon Lemay

Overcoming the Intrinsic Instability of Perovskites Materials and Devices. This project aims to improve the intrinsic stability of metal halide perovskite energy materials for advanced optoelectronic applications. The key concept is to suppress the phase-segregation for alloyed perovskite by interstitial management as well as develop low-temperature crystallization for non-alloyed perovskite through rational design of the intermediate phase evolution, which has the potential to generate new knowledge in addressing the key challenge on the operational stability of perovskite devices. The outcomes are expected to deliver valuable intellectual property to accelerate the commercialization of perovskite technology, enabling low-cost utilization of solar energy for a sustainable and low carbon-emission economy.. Scheme: Discovery Early Career Researcher Award. Field: 4016 - Materials Engineering. Lead: Dr Meng Zhang

A geospatial toolkit to assess community risk to environmental change. This project seeks to strengthen our understanding of the role of environmental change in driving patterns of community risk, by building a spatially and temporally explicit model, and a risk index that will be designed with input from decision makers. This project expects to improve the implementation of geospatial tools for risk assessment using an innovative approach based on evidence and practice. Expected outcomes include increased and optimal implementation of geospatial data in Australian systems, and enhanced research capacity to proactively respond to environmental change.. Scheme: Discovery Early Career Researcher Award. Field: 4202 - Epidemiology. Lead: A/Prof Aparna Lal

Accessing Liquid Noble Metals for Low Temperature Chemical Reactions. We will explore noble metals in liquid form at low temperatures. We will show that while noble metals melting points are above 1000°C, a gallium matrix will allow their existence in liquid form at low temperatures (<75°C). A variety of noble metal gallium alloy combinations will be investigated for their catalytic activities which are expected to show very high kinetics. We will study both bulk and low dimensional analogues to understand the atomic dispersion of noble metals on interface and in the core of the alloys, for discoveries regarding the liquid state catalytic properties of the mixes. Subsequently, model chemical reactions will reveal the enhancement of the kinetics and what the project can offer to industrial innovations. . Scheme: Discovery Projects. Field: 4016 - Materials Engineering. Lead: Prof Kourosh Kalantar-zadeh

Fast Precision Robust Control of Resonant Flexible Systems. The project aims to produce new control system design tools to enable fast precision control of advanced engineering systems encorporating flexible structures. This should enable improved speed and accuracy in control systems for precision instruments such as atomic force microscopes along with improving control system performance in areas of precision engineering such as semiconductor manufacturing, robotics and microelectromechanical systems. The outcomes are expected to be new control system synthesis and modelling tools enabling fast and highly accurate control of industrial systems using nonlinear and switching elements and achieving high levels of robustness. This will benefit Australian precision manufacturing industries.. Scheme: Discovery Projects. Field: 4007 - Control Engineering, Mechatronics and Robotics. Lead: Prof Ian Petersen

A next-generation whole parasite bovine Babesia vaccine. . In Australia, Babesia parasites cause most of the severe and often fatal cases of cattle-tick fever, a globally significant tick-borne disease. It can be prevented by a live-attenuated parasite vaccine which has critical limitations of a 4-day shelf-life and risk of severe disease if administered to adult cattle. This project aims to evaluate in cattle a novel whole parasite Babesia bovis vaccine that cannot cause disease and can be preserved as an off-the-shelf product without losing efficacy. The expected outcome is a significantly improved vaccine for a major infectious disease that affects primary food production. As the disease imposes a major economic burden, it will have great benefit for the Australian livestock industry. . Scheme: Discovery Projects. Field: 3003 - Animal Production. Lead: A/Prof Danielle Stanisic

High specificity nanosensors for glycobiology . This project aims to develop high specificity glycosensors for identifying and characterising carbohydrates. These glycosensors are expected to generate detailed information on carbohydrate stereochemical structure and how this controls protein-carbohydrate binding and other interactions fundamental to biochemical processes. This innovative nanotechnology aims to deliver a new capability for understanding cellular recognition and antigen binding mechanisms. The expected outcomes are new tools for glycobiology and research into carbohydrate structure-function relationships, strengthening Australia’s global reputation in nanosensors with an incisive analytical technology for biomedical sciences and the many industries utilising carbohydrates.. Scheme: Discovery Projects. Field: 3401 - Analytical Chemistry. Lead: Prof Ewan Blanch

Pathways to semelparity versus early maturity in animals and plants. The project aims to resolve an important but unresolved question in life history evolution and ecology- which mechanisms and constraints lead to semelparity (breeding once, which is rare), and which lead to fast life history (breeding early, which is common) in animals and plants. Theory predicts that both may be adaptations to schedules of adult death. Understanding why males and females have either semelparous or fast life history strategies is crucial to predicting survival of harvested and threatened species under pressure from climate change, drought, predators, and diseases that kill adults. Expected project outcomes include improved ability to address agents of decline of threatened animals and plants including semelparous species.. Scheme: Discovery Projects. Field: 3103 - Ecology. Lead: A/Prof Diana Fisher

Torres Strait Islander History: Sport, Culture and Identity. This project aims to investigate sport as a means of understanding the cultures, identities and history of Torres Strait Islanders. Through a community-centred approach, and a project team including Torres Strait Islanders, the project challenges versions of Australian history that marginalise the Strait or conflate Islanders with Aboriginal people. Expected outcomes of this project include a more nuanced history of Indigenous Australia, a significant body of repatriated resources on Islander sport and increased involvement of Islander communities in the history-making process. Anticipated benefits include a multifaceted contribution to reconciliation and better understanding of our unique and complex national identity.. Scheme: Discovery Projects. Field: 4501 - Aboriginal and Torres Strait Islander Culture, Language and History. Lead: A/Prof Frederick Osmond

Biomass-derived Carbon Dots Enable Flexible, On-Demand Hydrogen Delivery . Methanol is a promising liquid hydrogen carrier for long distance H2 transportation and exportation, because it is rich in hydrogen content, cheap, recyclable between methanol-formaldehyde and easier to manufacture from renewable resources including biomass waste. The critical bottleneck in adopting methanol as the carrier is the demanding dehydrogenation process. The project aims to create a new class of photocatalyst based on biomass-derived carbon nanodots grown on transition metal (di)chalcogenide nanosheets that can effectively enable a light-controlled methanol H2 release of desired quantity. The key outcomes will be a new class of photocatalysts and flexible, on-demand hydrogen delivery technology for liquid hydrogen carriers.. Scheme: Discovery Projects. Field: 4004 - Chemical Engineering. Lead: Prof Qin Li

How do vortices live in spatio-temporally complex flows? The project aims to understand the fundamental mechanism of vortices occurring in flows involving spatio-temporal complexity, by using the combination of dynamical systems theory and asymptotic analysis. This innovative combined mathematical analysis will be coupled with sophisticated computations to be enabled by the international interdisciplinary collaboration between the Mathematics and Engineering at Australia and Japan. The expected outcomes are breakthroughs in the fundamental understanding of turbulence. This should lead to significant insight into better turbulent modellings used in, for example, wide range of engineering, physiological and geophysical flows.. Scheme: Discovery Projects. Field: 4012 - Fluid Mechanics and Thermal Engineering. Lead: Dr Kengo Deguchi

A new perspective on how we learn motor skills: two adaptation classes? The capacity to adapt and acquire movement skills is essential for success in almost every aspect of our lives. This project will test the idea that there are two fundamentally distinct classes of motor learning processes in the brain that are driven by different error types. Using brain recordings, robotic perturbation of movement, and novel variations of classical learning paradigms, the project aims to reveal the neurocomputational properties of these proposed adaptation classes across a range of sensorimotor learning paradigms. The knowledge gained from this project may identify new strategies for adapting movements that are widely applicable to industry, defence, sport, and health.. Scheme: Discovery Projects. Field: 5202 - Biological Psychology. Lead: Prof Timothy Carroll

Defining the microenvironmental regulators of spleen function and immunity. The spleen is an important organ that is present in almost all vertebrates and is a critical site for the induction of systemic immune responses. The current paradigms of spleen biology are mostly derived from rodent studies, but the cellular biology of the spleen in humans remains poorly defined. Using novel tools, advanced transcriptomics and imaging techniques this project aims to reveal the functions of stromal cells in the spleen in humans and to define the fundamental roles of spleen stromal cells in long-lived immunity. The anticipated outcomes are to build Australia’s research capacity and to generate new knowledge of significance for our fundamental understanding of the spleen and the role of this tissue in the immune system.. Scheme: Discovery Projects. Field: 3204 - Immunology. Lead: Prof Scott Mueller

Redefining the immune landscape of the human ocular surface. At the ocular surface, the cornea and limbus need to mount effective immune responses to maintain corneal transparency for clear vision. The current paradigm is that the human cornea houses the same innate immune cell subsets (dendritic cells and macrophages) as naïve mice in pathogen-free facilities. Our pilot data challenge this premise, with early evidence that innate and adaptive cells (T cells) coexist in normal human corneas. Integrating state-of-the-art techniques, we will advance understanding of immune regulation at the human ocular surface by comprehensively defining immune cell biology and dynamics. We will define the effect of age on immune cells in these tissues, and relationships between the tear proteome and cell behaviours.. Scheme: Discovery Projects. Field: 3204 - Immunology. Lead: Prof Laura Downie

The viral fusosome: a modular machinery for cargo delivery to target cells. The delivery of proteins, RNA and DNA into cells is a critical process in normal cellular biology, virus infection and biotechnology applications such as gene editing. Enveloped viruses achieve this maneuver with exquisite efficiency and specificity using a complex machinery mediating their fusion with cellular membranes for stealth genome delivery. Remarkably, all characterised viral fusion proteins belong to only 3 classes defined >16 years ago and sharing surprisingly conserved mechanisms. We identified a novel class of fusion proteins with unique architecture in ubiquitous insect viruses. The Project will elucidate the structural and functional hallmarks of this fusion machinery providing a platform for its engineering.. Scheme: Discovery Projects. Field: 3101 - Biochemistry and Cell Biology. Lead: Prof Fasseli Coulibaly

Lattice Panel Based Optical Apertures for Optical Wireless Networks . Future work and homes will demand superfast wireless connectivity supported by optical fibre networks providing high speeds into our buildings. The technology gap, however, is a system to deliver this level of connectivity to our wireless mobile devices. Addressing this need, this innovative project proposes a novel architecture of lattice panel apertures based on arrays of phased arrays that can establish and steer multiple optical beams simultaneously. It will investigate these system architectures, demonstrating their feasibility. By transforming broadband wireless into the future of optical mobile networking, the project outcomes will extend to every connected office and home, benefiting Australia’s economy and national security. . Scheme: Discovery Projects. Field: 4006 - Communications Engineering. Lead: Prof Ampalavanapillai Nirmalathas

Rational design of array-based nanozyme sensors. The project aims to obtain a deep understanding of molecular interactions at the nano-bio interface, and use this knowledge to develop a robust sensor technology for the rapid detection of foodborne pathogens in complex samples. The project proposes to employ an innovative approach that mimics the senses of smell and taste, where an array of aptamers are expected to work in synergy to precisely identify a target, providing an edge over current sensing technologies. Expected outcomes include a ready-to-go analytical tool for the detection of food contaminants. This should provide significant economic, health, and social benefits through supporting Australian food and health sectors, and the potential commercialisation of sensor technologies.. Scheme: Discovery Projects. Field: 3106 - Industrial Biotechnology. Lead: Prof Vipul Bansal

Using animal-borne sensors to unravel East Antarctic coastal productivity. This project will examine the mechanisms underpinning the high productivity in Antarctic coastal polynyas, which are ice-free oases within the sea ice supporting abundant marine life. The study expects to generate essential new biochemical and biological observations using autonomous platforms to understand phytoplankton dynamics in these inaccessible habitats along Australia’s Antarctic Territory. Expected outcomes include novel insight into the role of iron supply from melting glaciers in supporting marine production. This should reduce the high uncertainty in prognoses for polynya activity under anthropogenic climate change, and support Australia’s international leadership in conservation and management of important Antarctic ecosystems.. Scheme: Discovery Projects. Field: 3708 - Oceanography. Lead: Dr Sophie Bestley

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

Making Strong Alloys Ductile and Hydrogen-Tolerant via Tuning Nanogradients. This project aims to develop a novel design concept of gradient segregation engineering (GSE) to produce high-performance alloys. The innovative GSE will synergistically introduce a chemical gradient via grain boundary segregation and a physical gradient by microstructure control to simultaneously achieve an excellent strength-ductility combination and exceptional resistance to hydrogen embrittlement. This project expects to create new fundamental knowledge and provide critical perspectives for future mechanistic alloy design. The results will enhance Australia’s capacity to develop next-generation advanced alloys to underpin current and emerging industrial applications and strengthen the country’s leading position in materials engineering.. Scheme: Discovery Projects. Field: 4016 - Materials Engineering. Lead: A/Prof Xianghai An

Fundamental research advancing remanufacturing with a 3D printing technique. 3D printing manufactures items directly from a computer model. This project aims to develop a computational tool for applying direct laser metal deposition, a 3D-printing method, to repair metallic components and develop a way to predict the remaining life of the remanufactured components. The tool should optimise use of this printing method and improve the quality of repaired components. The research expects to validate the tool for simulating the printing process, provide a better heat treatment during repair, and allow safe prediction of the service life of repaired components. This research should benefit the Australian manufacturing industry and reduce resource use by helping apply this 3D printing method in remanufacturing.. Scheme: Discovery Projects. Field: 4017 - Mechanical Engineering. Lead: Prof Wenyi Yan

Break the deadlock in corrosion research to prevent infrastructure collapse. Corrosion destroys one-quarter of the world’s annual steel production and costs the Australian economy $30 billion each year. This project targets a crucial missing link in understanding the structure and dynamics of the atomic lattices of corroded steel and the degradation of its mechanical strength. By combining advanced electrochemical and mechanical measurements with dynamics simulation of atomic lattices of corroded steel, this project will produce the first concerted picture of corrosion induced strength degradation with a particular focus on real industrial conditions. This promises to guide the ongoing diagnosis of corrosion damages to steel, effectively preventing the collapse of corroded infrastructure.. Scheme: Discovery Projects. Field: 4005 - Civil Engineering. Lead: Prof Chun-Qing Li

The cost of keeping gruesome images from the world. This project aims to investigate one of society’s most invisible ‘frontline’ trauma workforces—the online content moderators responsible for limiting the public’s exposure to distressing and sensitive content on social media. Using a series of rigorous experiments, and cutting-edge psychological and physiological assessment techniques, the research will advance our understanding of the impact of indirect trauma on mental health. Expected outcomes include novel empirical evidence for preventative strategies that will predict, monitor and reduce negative mental health outcomes. This will provide significant global benefits to people with indirect trauma experiences, such as defence and forensic personnel.. Scheme: Discovery Projects. Field: 5201 - Applied and Developmental Psychology. Lead: Prof Melanie Takarangi