Grants & Opportunities

Towards predictive 4D computational models for the heart. This project aims to develop novel high-performance numerical algorithms for multiscale and multiphysics PDEs with dynamic interfaces, the development and analysis of a novel PDE system modelling the electromechanics of heart and torso, and the combination of these numerical techniques and models to deliver predictive tools for patient-specific simulations of the cardiac function. It involves the design and mathematical analysis of space-time variational discretisations on embedded meshes, 4D computational geometry algorithms for numerical integration and multilevel solvers. By combining scientific computing and machine learning, one anticipated outcome of this research is a new generation of nonlinear PDE approximations and solvers.. Scheme: Discovery Projects. Field: 0103 - Numerical and Computational Mathematics. Lead: Prof Santiago Badia

The Role of Energy Absorbing Rubber Grid on Ballast Track Performance. Breakage and excessive displacement of ballast lead to instability and regular maintenance of railways. The project aims to study the fundamental mechanics of ballast aggregates interacting with the apertures of recycled-Rubber Energy Absorbing Grids (REAG). The role of REAG on enhanced track performance by damping the cyclic wheel loading and impact will be quantified via rigorous mathematical methods complementing a computer-based numerical model and validated by laboratory & field data. When placed within the rail substructure REAG will enable reduced ballast movement and breakage while attenuating noise/vibration. The research outputs will facilitate improved rail track design enabling enhanced longevity and reduced cost of maintenance.. Scheme: Discovery Projects. Field: 0905 - Civil Engineering. Lead: Prof Buddhima Indraratna

Circadian photoreceptor sensitivity and impacts of modern lighting on sleep. Light has powerful non-visual effects, including effects on sleep. These non-visual effects are mediated by cells in the eye that are most sensitive to blue light. There are large individual differences in sensitivity to non-visual effects of light that are not understood and that would give great insight into suboptimal sleep, which has become widespread in modern society. This study will be the first systematic examination of individual differences in the effect of blue light on sleep and will uncover how alterations in the gene responsible for the effects of blue light on sleep (OPN4) contribute to these differences. This will lead to scalable individualised solutions to the unmet problem of how modern light environments impact sleep.. Scheme: Discovery Projects. Field: 1701 - Psychology. Lead: A/Prof Andrew Phillips

Estimation and Control of Noisy Riemannian Systems. Many application areas such as satellite control, computer vision, coordination of rigid bodies, require the estimation and control of systems subject to geometric constraints. Most current algorithms for doing this are deterministic and can fail catastrophically in the presence of noise. This project aims to provide: (i) Methods for analysing and then redesigning deterministic algorithms to ensure stability in the presence of noise; (ii) New design methods that deal with noise in an optimal way; (iii) Noise resistant methods for distributed consensus seeking systems and cooperative control systems. The outcomes will advance and benefit spatio-temporal data analysis and coordination in areas such as transport, health and video-security.. Scheme: Discovery Projects. Field: 0906 - Electrical and Electronic Engineering. Lead: Prof Victor Solo

Singular solutions for nonlinear elliptic and parabolic equations. The analysis of many models fundamental to physical and biological sciences is obstructed by singularities. This project aims to discover and classify the singular solutions for two important types of nonlinear equations: elliptic and parabolic. The project expects to generate novel methods to decipher singularities by using innovative approaches from geometric analysis and dynamical systems. Expected outcomes of this project include new and powerful tools to advance a more general theory of singularities. This should provide significant benefits, such as new mathematical knowledge on key issues on singularities lying at the forefront of international research and enhanced expertise in an area of worldwide recognition for Australia.. Scheme: Discovery Projects. Field: 0101 - Pure Mathematics. Lead: Prof Florica Cirstea

Developing Ecosystem Services Economies for northern Australia. The project aims to advance economic opportunities for Indigenous communities across Northern Australia by developing culturally appropriate ecosystem services economies. The project will offer new alternatives for collectively addressing chronic Indigenous socio-economic issues and pressing environmental issues. Expected outcomes include a co-developed ecosystem services economies business model with a toolkit, involving Indigenous and business stakeholders, for establishing innovative enterprises across northern Australia. Key benefits include new ecosystem services-based enterprises; sustainable land sector development; jobs in remote locations; improved well-being of Indigenous peoples; and better environmental management. . Scheme: Discovery Projects. Field: 0502 - Environmental Science and Management. Lead: Prof Kamaljit Sangha

Locating Giurgola: From Philadelphia School to Global Practice. This project aims to conduct the first major systematic assessment of the architectural career of Romaldo Giurgola (1920-2016), the principal architect of Australian Parliament House. It will review all known archives relating to his life and works, including significant collections in North America and Australia, and it will survey the full range of his architectural projects. The project expects to result in a new and complete assessment of Giurgola's architecture, figuring important Australian buildings into an international landscape of professional practice. The primary outcome of this project will be a large critical catalogue, presenting the full extent of his career for the first time and locating APH in that career in new terms.. Scheme: Discovery Projects. Field: 1201 - Architecture. Lead: A/Prof Cameron Logan

Laser-free on-chip super-resolution microscopy. The project aims to develop a compact, cost-effective on-chip super-resolution microscope through an innovative combination of imaging algorithms, optics and integrated photonics. This project addresses limitations in imaging algorithms that increase laser system complexity and constrain imaging speed and applications, as well as nanostructure fabrication issues. Expected outcomes include the discovery of emitter self-interference microscopy, new knowledge in imaging, photonics and biophysics, the world’s fastest super-resolution technology, compact on-chip nanoscopy that can be added to existing technology and proof of concept in three areas. Benefits are anticipated in commercialisation, improved photonics devices and usage in biophysics.. Scheme: Discovery Projects. Field: 1007 - Nanotechnology. Lead: Prof Lan Fu

Data analytics-based tools and methods to enhance self-regulated learning. This project aims to develop student self-regulated learning skills by harnessing the potential of Big Data analytics. The project expects to generate new knowledge at the intersection of learning analytics, educational technology, learning sciences and teaching practice resulting from novel data collection and analysis tools and methods. The outputs are expected to include insights into metacognitive, motivational, and technical issues facing analytics-based personalised feedback. The outcomes are intended to offer benefits for developing pedagogical and the design of educational technology. The outcomes can result in improved student learning outcomes in higher education to ensure graduates are prepared for the digital economy.. Scheme: Discovery Projects. Field: 1303 - Specialist Studies In Education. Lead: Prof Dragan Gasevic

The Great Barrier Reef in 2100. Our research aims to answer fundamental geomorphic questions about the future of coral reefs, focusing on the Great Barrier Reef (GBR). We will develop cutting-edge, fully open-source numerical models to quantify the eco-morphodynamic evolution of the GBR under IPCC climate-change scenarios. Our geomorphic numerical models will consider biotic/abiotic feedbacks including synergistic effects of multiple stressors such as waves, temperature, acidification and sediment transport, at individual reef scales. We will model the future of the GBR’s ecosystem-services, allowing for a quantum leap in the geomorphic knowledge and understanding of coral reef ecosystems. Expected outcomes include a gamechanger tool for future management of the GBR.. Scheme: Discovery Projects. Field: 0403 - Geology. Lead: Prof Ana Vila Concejo

Communities, Kava, Court Orders: The Ways of Possessing the Pacific City. This project aims to understand how urban tenure security is negotiated, claimed and/or recognised amid increasing stress on urban resources and competing potential sources of value for urban land. Through small-scale community-facing research, it intends to produce evidence of how residential tenure works on customary lands around Port Vila, Vanuatu. Expected outcomes include case studies and typologies showing the types of tenure relationships in place. This should have significant benefits for government and donors working to prevent displacement and developing plans for inclusive urbanisation into the future. Local populations should also benefit through increased awareness of the value and standing of customary tenure arrangements. . Scheme: Discovery Projects. Field: 1205 - Urban and Regional Planning. Lead: Dr Jennifer Day

Connections for hybrid steel-timber-concrete structures. Connections play a vital role in overall performance, reliability, and adaptability of civil structures. This project aims to develop innovative, easy to fabricate and efficient connections for hybrid structural systems that fully exploit advantages of steel, concrete and engineered timber to reduce the self-weight, cost and negative environmental impact and enhance opportunities for deconstruction, reusing and upgrading of the structures. Structural performance of the connections will be assessed by laboratory testing and advanced numerical modelling. Comprehensive knowledge on stiffness, strength, and ductility and world-first provisions for safe and cost-effective design of the hybrid steel-timber-concrete structures are generated.. Scheme: Discovery Projects. Field: 0905 - Civil Engineering. Lead: Prof Hamid Valipour

Linking terrestrial–aquatic fluxes to rectify the Australian carbon balance. This project aims to rectify the Australian carbon balance by determining the amount of terrestrial carbon that is lost to streams and rivers across the country. Through a novel integration of high-resolution hydrochemical and gas measurements, remote sensing and machine learning algorithms, the project intends to generate new knowledge about the links between terrestrial carbon sequestration and aquatic carbon export. Expected outcomes include a refined estimate of the net carbon sequestration potential across Australian biomes and seasons. This should provide significant benefits such as avoiding misalignment of greenhouse gas abatement policies and advancing carbon cycling models and predictions.. Scheme: Discovery Projects. Field: 0501 - Ecological Applications. Lead: Dr Clement Duvert

Unravelling the mechanics of particle deposition at the micro-scale. This project aims to discover the mechanisms responsible for the interactions between aerosol particles and surfaces in a range of air flow conditions. The project expects to transform our understanding of particle deposition through a combination of novel laser-based diagnostic techniques, optical coherence tomography, and state of the art particle formulation methodologies. Expected outcomes of the project include delivery of new methods to optimise particle deposition, development of tunable powder formulations, as well as definition of particle-surface interaction mechanisms in flows. The project should provide significant benefits to particle systems for applications ranging from additive manufacturing to aerosol delivery.. Scheme: Discovery Projects. Field: 0904 - Chemical Engineering. Lead: Prof Hak-Kim Chan

Monolithic Solar Thermal Photocatalytic Membrane for Hydrogen Production. This ambitious project aims to develop a new concept of monolithic membranes composed of photocatalysts embedded in highly efficient solar thermal graphene. Such a membrane will be first of its kind and is able to utilise full solar spectrum for scalable seawater desalination and direct splitting to produce hydrogen without the need to concentrate sunlight. Expected outcomes include chemically and structurally tailored membranes and 2D floating prototypes for real life hydrogen production, and in-depth understanding of working mechanism to facilitate up-scaled renewable hydrogen generation. Significant benefits in minimising fossil fuel consumption, increasing energy security, and expanding competitive clean energy industry are promised.. Scheme: Discovery Projects. Field: 0912 - Materials Engineering. Lead: Prof Tianyi Ma

Harmonic analysis of Laplacians in curved spaces. Harmonic Analysis is a branch of mathematics which is interrelated to other fields of mathematics like complex analysis, number theory and partial differential equations (pdes) with many applications in engineering and technology. This project aims to solve a number of difficult fundamental problems at the frontier of harmonic analysis in understanding Laplacians in curved spaces. Such Laplacians control the propagation of heat and waves on manifolds and Lie groups, arising in mathematical physics and quantum mechanics. Expected outcomes are the solutions of dispersive equations and the framework of singular integrals in curved spaces; new ideas and techniques in harmonic analysis developed; and training of Australian future mathematicians.. Scheme: Discovery Projects. Field: 0101 - Pure Mathematics. Lead: A/Prof Ji Li

Microfluidics with core-shell beads: handling liquids like solids. Reducing waste of consumables in chemical reactions promises to solve environmental problems as well as enable novel applications in space. This project aims to establish a revolutionary fluid handling technology that lowers waste in the labs and in satellites. The project deciphers the fundamental physics behind our recent discovery of encapsulating a tiny liquid content in a solid shell, allowing for handling liquid samples like solid particles. Examples of the benefit of this project are more precise detection of bacteria on earth and compact reactors in space. The research outcomes are instrumental for promoting a clean environment, good health, and creating new business opportunities, particularly in space industry, for Australians.. Scheme: Discovery Projects. Field: 0913 - Mechanical Engineering. Lead: Prof Nam-Trung Nguyen

The worlds next door: terrestrial exoplanets with the TOLIMAN space mission. This project aims to to explore our nearest neighbour star system, Alpha Centauri, for the first time probing for exoplanets with physical characteristics that resemble those of Earth. The finding of any such world, with the potential to support a biosphere like our own and lying only 4 light-years away, would profoundly alter our view of our place in the universe. The primary outcome of this project will be the design, construction, launch and operation of a novel and innovative space telescope: the TOLIMAN mission. This profoundly benefits the Australian space and university sectors, partnering them with international agencies to deliver marquee science with global impact: the search for our first stepping stone to interstellar space.. Scheme: Linkage Projects. Field: 0201 - Astronomical and Space Sciences. Lead: Prof Peter Tuthill

High-productivity ammonia electrosynthesis. The aim of this project is to develop and demonstrate high-performance devices for ammonia production from renewables by a scalable electrolysis method. This will be achieved by experimental and modelling investigations of the nitrogen reduction reaction to guide the design of tailor-made cathodes. New knowledge in catalysis and materials science is expected to be generated. The target outcome of the project is a sustainable and affordable ammonia synthesis method as an alternative to the current fossil-fuels-based and excessively greenhouse-emitting process. The technology to be developed in this project is anticipated to be of significant benefit to the Australian agriculture sector as a local, on-demand source of low-cost fertilisers.. Scheme: Linkage Projects. Field: 0306 - Physical Chemistry (Incl. Structural). Lead: A/Prof Alexandr Simonov

Three-dimensional Bayesian Modelling of Geological and Geophysical data. The project aims to develop technologies enabling rapid informed decision-making related to the management of natural resources, including critical metals, copper and water. This new technology will support a greener future, securing our energy future, our access to clean water and reduce the mining footprint. Expected outcomes include an enhanced capability in interoperable, integrated three-dimensional geological and geophysical modelling in order to predictively characterise sub-surface geology. The outcome will be an open-source forecasting dashboard enabling decision making while considering underlying risk related to resource extractions and management with significant benefits to the Australian society (lower emissions, clean water).. Scheme: Linkage Projects. Field: 0403 - Geology. Lead: Dr Laurent Ailleres

Cave microbial metabolism as a missing biogeochemical sink. The aim of this project is to unveil the microbial biodiversity, novel metabolic capabilities and chemosynthetic primary production of subsurface ecosystems, such as those found in caves. Leveraging a powerful blend of geospatial, molecular and biogeochemical approaches this project expects to identify the microbial basis of subsurface biogeochemical processes driving the earth’s major elementary cycles. Expected outcomes include a predictive framework to assess and upscale the impact of these microbial communities on the environment. Benefits include predicting and responding to climate risks, such as the desertification of agricultural soils, by uncovering how microorganisms respond to nutrient and carbon depletion.. Scheme: Discovery Early Career Researcher Award. Field: 3107 - Microbiology. Lead: Dr Sean Bay

Hierarchical Ta-Ti lattice materials by 3D printing and nanofabrication . This project aims to develop a novel approach to the manufacture of hierarchical Ta-Ti lattice materials with a fine nanoporous Ta surface through capitalizing on the advantages of metal 3D printing and a unique post nanofabrication process. This project expects to generate new fundamental knowledge in the design and manufacture of hierarchical metal lattice materials. Expected outcomes include a new advanced manufacturing method and a new class of highly biocompatible hierarchical Ta-Ti lattice materials. The former should benefit the Australian Manufacturing Industry for the manufacture of a variety of novel metal lattice materials or products while the latter has the potential for applications as implant materials.. Scheme: Discovery Early Career Researcher Award. Field: 4016 - Materials Engineering. Lead: Dr Tingting Song

Climate Change: The Role of Reporting, Auditing and Executive Remuneration . This project addresses the need for corporate disclosures on climate-related risks. It aims to generate new knowledge about reporting and auditing of climate-related information and how these metrics are incorporated into executives’ remuneration. Utilizing the latest global developments, the project will highlight best practices under both voluntary and mandatory reporting regimes and provide cross-jurisdictional evidence on the impact of mandatory reporting schemes. It will also test the effectiveness of reporting, auditing and remuneration in achieving carbon emissions reductions and meeting capital market demands. The project will lead to improved capital market efficiency and informed policy making in Australia and internationally. . Scheme: Discovery Early Career Researcher Award. Field: 3501 - Accounting, Auditing and Accountability. Lead: A/Prof Shan Zhou

New insights into how the brain interprets visceral and somatic sensations. Sensory nerve fibres monitor normal and abnormal stimuli in our body tissues, sending this information to the brain. I study the sensory pathways of the respiratory system which protect the lungs from harmful stimuli, such as inhaled pollutants or smoke. I discovered that respiratory sensory pathways interact with sensory circuits in the brain arising from other body tissues. The goal of this project is to investigate one example of this interaction; the convergence of visceral and somatic sensory pathways onto a brain circuit that regulates the intensity of the sensations that are experienced. This project addresses the fundamental question of how the brain processes two competing noxious sensations.. Scheme: Discovery Early Career Researcher Award. Field: 3209 - Neurosciences. Lead: Dr Alice McGovern

Reaching deeper into neuronal networks using optical physics. Understanding the functions and intricacies of the brain is a fundamental challenge in scientific research. This project aims to develop new technologies to construct a microscope able to alter and make sense of neuronal activity in situ. This project also aims to investigate the precise role of a key brain region involved in sensory processing: the locus coeruleus. The results will reveal how this brain region influences brain dynamics as well as behaviour. Expected outcomes include state of the art microscopes, high impact publications, and international collaborations. The anticipated benefits are the high quality training of the Australian workforce and further establishment of Australia as a leader in microscopy and neuroscience.. Scheme: Discovery Early Career Researcher Award. Field: 3109 - Zoology. Lead: Dr Itia Favre-Bulle