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
A Concurrent Multiscale Model for Improved Prediction of Drying Process. This project aims to develop an innovative multiscale model for food drying, which integrates spatial and temporal nonlinear behaviours at different scales. The proposed unifying theory will capture dynamic micro level features and upscale them to macro level features through a concurrent bridging scheme. As cellular elements critically govern the drying process, the fundamental understanding captured through this theory wi ....A Concurrent Multiscale Model for Improved Prediction of Drying Process. This project aims to develop an innovative multiscale model for food drying, which integrates spatial and temporal nonlinear behaviours at different scales. The proposed unifying theory will capture dynamic micro level features and upscale them to macro level features through a concurrent bridging scheme. As cellular elements critically govern the drying process, the fundamental understanding captured through this theory will lead to more accurate prediction of drying kinetics, deformation and quality changes, and hence the development of efficient drying systems. This project will overcome a longstanding research problem and position Australia at the forefront in world drying research to reap substantial economic benefits for Australia.Read moreRead less
Transforming Australian bio-based industries through multiscale modelling. Agricultural and forestry biomass can be converted into feedstocks for production of biofuels and biomaterials via synthetic biology. A key challenge is the complex biomass microstructure renders it highly resistant to conversion, and pretreatment is crucial for enhancing process efficiency. Micro-CT imaging will enable particle characterisation and identification of changes in the fibre composition during pretreatment. T ....Transforming Australian bio-based industries through multiscale modelling. Agricultural and forestry biomass can be converted into feedstocks for production of biofuels and biomaterials via synthetic biology. A key challenge is the complex biomass microstructure renders it highly resistant to conversion, and pretreatment is crucial for enhancing process efficiency. Micro-CT imaging will enable particle characterisation and identification of changes in the fibre composition during pretreatment. This information will be used to create a virtual biomass particle model for an in silico investigation to inform optimal process design. The framework will transform the way biomass is processed, contributing to the growth of the Australian bio-manufacturing industry by making it more productive, profitable and sustainable.Read moreRead less