Improving crops from the ground up: genetic solutions to optimise roots. This project aims to develop future crops with optimised root systems by overcoming genetic constraints that currently restrict their potential. Exploiting advances in genomics, transcriptomics, epigenomics and genome editing, this project expects to advance understanding of the biology and genetic controls of root development and responses to concurrent stressors, including drought, nutrient deficiency and soil-borne disea ....Improving crops from the ground up: genetic solutions to optimise roots. This project aims to develop future crops with optimised root systems by overcoming genetic constraints that currently restrict their potential. Exploiting advances in genomics, transcriptomics, epigenomics and genome editing, this project expects to advance understanding of the biology and genetic controls of root development and responses to concurrent stressors, including drought, nutrient deficiency and soil-borne disease. It is anticipated that project outcomes will support the development of crops equipped with novel root traits, enhancing resource-use efficiency and yield stability amid climate variability. This globally relevant research is designed to benefit the sustainability and profitability of the Australian grains industry.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100854
Funder
Australian Research Council
Funding Amount
$461,249.00
Summary
Model-directed bioengineering strategy for accelerating crop improvement. The aim is to use an advanced mechanistic crop model to investigate the interacting plant physiological processes that define yield consequences, using a sorghum model. This will involve unravelling the complex relationship between leaf gas exchange properties and crop field performance. Through a unique combination of model prediction and gene editing to target the photosynthetic pathway and stomata, the research is expec ....Model-directed bioengineering strategy for accelerating crop improvement. The aim is to use an advanced mechanistic crop model to investigate the interacting plant physiological processes that define yield consequences, using a sorghum model. This will involve unravelling the complex relationship between leaf gas exchange properties and crop field performance. Through a unique combination of model prediction and gene editing to target the photosynthetic pathway and stomata, the research is expected to gain a deep mechanistic understanding of the underpinning processes and drive the transfer of promising bioengineering targets into crops. The research is expected to discover new avenues for crop improvement, and significantly benefit crop breeding and food production capacity.Read moreRead less
Supersymmetry and supergravity: new approaches and applications. This project aims to advance our understanding of supersymmetric quantum field, gravity, and higher-spin theories. Supersymmetry and supergravity play crucial roles in modern developments in fundamental particle physics and cosmology. They also have rich connections with many branches of mathematical physics. Major conceptual questions in the description of general supergravity-matter couplings are still unsolved. By performing sta ....Supersymmetry and supergravity: new approaches and applications. This project aims to advance our understanding of supersymmetric quantum field, gravity, and higher-spin theories. Supersymmetry and supergravity play crucial roles in modern developments in fundamental particle physics and cosmology. They also have rich connections with many branches of mathematical physics. Major conceptual questions in the description of general supergravity-matter couplings are still unsolved. By performing state of the art analysis in supergravity and holographic dualities, the project will advance our understanding of quantum gravity, black holes, and cosmology placing Australia at the forefront of these important research fields.Read moreRead less
Reaching new frontiers of quantum fields and gravity through deformations. This project aims to reach new frontiers in quantum field and gravity theories. These underpin systems ranging from semi-conductors to particle collisions and the quantum behavior of black holes. An obstacle is that these theories are notoriously hard to solve. This project proposes to tackle this longstanding problem by using new deformations, symmetries and dualities that have attracted widespread attention. Expected ou ....Reaching new frontiers of quantum fields and gravity through deformations. This project aims to reach new frontiers in quantum field and gravity theories. These underpin systems ranging from semi-conductors to particle collisions and the quantum behavior of black holes. An obstacle is that these theories are notoriously hard to solve. This project proposes to tackle this longstanding problem by using new deformations, symmetries and dualities that have attracted widespread attention. Expected outcomes will include innovative techniques that will greatly enhance and interconnect our knowledge of field theories and quantum gravity, together with new discoveries in quantum-corrected geometries. A new network of domestic and international experts will largely benefit the fields of theoretical and mathematical physics.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL180100139
Funder
Australian Research Council
Funding Amount
$2,973,547.00
Summary
Processes of plant growth that impact agriculture and horticulture. The project aims to discover the genes and processes that control plant shoot architecture, which is a major driver of yield in field, horticultural and forestry crops. Shoot branching is the result of the complex interplay of genes, environment and crop management. By investigating cellular processes governing growth and development, as well as physiology and molecular genetics, this project will enhance Australian capacity and ....Processes of plant growth that impact agriculture and horticulture. The project aims to discover the genes and processes that control plant shoot architecture, which is a major driver of yield in field, horticultural and forestry crops. Shoot branching is the result of the complex interplay of genes, environment and crop management. By investigating cellular processes governing growth and development, as well as physiology and molecular genetics, this project will enhance Australian capacity and multidisciplinary innovation. An improved understanding of shoot branching and how it may be manipulated will improve our knowledge of plant sciences that could contribute to agricultural expansion and food security in Australia and internationally.Read moreRead less
Food System Shocks: Managing Transitions to Future Food Security. Recent food system shocks such as bushfires, floods, drought, and the impact of Covid-19 on the harvesting and distribution of agricultural products, are having profound on-farm impacts. Farmers, as land managers, are on the front line of navigating these major disruptions whilst also maintaining continuity of supply that supports Australia's national and regional food security. Situating the farmer as the 'expert' of managing and ....Food System Shocks: Managing Transitions to Future Food Security. Recent food system shocks such as bushfires, floods, drought, and the impact of Covid-19 on the harvesting and distribution of agricultural products, are having profound on-farm impacts. Farmers, as land managers, are on the front line of navigating these major disruptions whilst also maintaining continuity of supply that supports Australia's national and regional food security. Situating the farmer as the 'expert' of managing and accommodating shocks, this project will co-produce a range of evidence-based transition and innovation scenarios for the horticultural industry to enhance future preparedness for shocks and support rural livelihoods. Read moreRead less
Unlocking the genetic and biochemical potential of kangaroo paws. Using cutting-edge gene technology and an interdisciplinary approach, this project aims to uncover the genes responsible for flower colour in the iconic kangaroo paws of Western Australia, and identify the compounds that produce the colours. The project expects to produce the first entire kangaroo paw genome and identify unique genetic variants and biochemicals underlying colour differences. This new knowledge should help horticul ....Unlocking the genetic and biochemical potential of kangaroo paws. Using cutting-edge gene technology and an interdisciplinary approach, this project aims to uncover the genes responsible for flower colour in the iconic kangaroo paws of Western Australia, and identify the compounds that produce the colours. The project expects to produce the first entire kangaroo paw genome and identify unique genetic variants and biochemicals underlying colour differences. This new knowledge should help horticultural programs to more easily breed varieties with desirable and highly marketable new colours, and could assist in conserving these amazing Australian plants.Read moreRead less
Mathematical and computational models for agrichemical retention on plants. Mathematical and computational models for agrichemical retention on plants. This project aims to build interactive software that simulates agrichemical spraying for multiple virtual plants reconstructed from scanned data. Mathematical modelling and computer simulation could offer an alternative to expensive experimental programs for agrichemical spraying of plants. This project will use contemporary fluid mechanics to bu ....Mathematical and computational models for agrichemical retention on plants. Mathematical and computational models for agrichemical retention on plants. This project aims to build interactive software that simulates agrichemical spraying for multiple virtual plants reconstructed from scanned data. Mathematical modelling and computer simulation could offer an alternative to expensive experimental programs for agrichemical spraying of plants. This project will use contemporary fluid mechanics to build practical mathematical models for droplet impaction, spreading and evaporation on leaf surfaces, and experimentally calibrate and validate the models. The software is expected to drive the development of agrichemical products that increase retention, minimise environmental impacts, and reduce costs for end-users.Read moreRead less
Developing a novel carbon negative fertiliser . Food security is vital to support our growing population. However, our increasing reliance on intensive farming systems necessitates increased fertiliser use, leading to increased water pollution and soil degradation - threatening both the Australian environment and food security. Increasing carbon storage capacity by soil and decreasing fertiliser use are two of the primary pathways for restoring the bio-support capacity of soils and reducing farm ....Developing a novel carbon negative fertiliser . Food security is vital to support our growing population. However, our increasing reliance on intensive farming systems necessitates increased fertiliser use, leading to increased water pollution and soil degradation - threatening both the Australian environment and food security. Increasing carbon storage capacity by soil and decreasing fertiliser use are two of the primary pathways for restoring the bio-support capacity of soils and reducing farming footprints. This innovative and first-of-its-kind project aims to develop a cost-effective, carbon negative fertiliser that reduces fertiliser inputs and increases soil carbon storageRead moreRead less
Novel Multilevel Modelling Framework to Design Advanced Food Drying Process. In this project, a novel multilevel modelling framework for food drying will be developed by integrating the micro, macro, and dryer scale transport process and considering the dynamic changes in the drying environment under the intermittent application of microwave energy (IMCD). This modelling framework will be the first comprehensive scientific tool for industry for developing next-generation food drying systems, whi ....Novel Multilevel Modelling Framework to Design Advanced Food Drying Process. In this project, a novel multilevel modelling framework for food drying will be developed by integrating the micro, macro, and dryer scale transport process and considering the dynamic changes in the drying environment under the intermittent application of microwave energy (IMCD). This modelling framework will be the first comprehensive scientific tool for industry for developing next-generation food drying systems, which are expected to deliver significant improvement in energy efficiency and product quality and reduction in drying time and food waste. Finally, based on the outcomes of the modelling framework, a smart IMCD drying system will be developed to demonstrate the feasibility of the framework in industry application.Read moreRead less