Advanced solar powered hydrogen production systems based on green algal cells. This project aims to enhance the efficiency of solar powered hydrogen production from water and will facilitate the co-production of H2 and oil through microalgal biofuel systems. This frontier science project will therefore deliver a process with high solar conversion efficiency and will deliver multiple product streams increasing profitability.
Deciphering the role of microRNAs during pathogen attack: new concepts for disease resistance in plants. Small non-coding RNAs called ‘microRNAs’ regulate diverse pathways in plants including plant defence against pathogens. This project will investigate the roles of plant microRNAs in response to four economically important viruses and compare these to a bacterial and a fungal pathogen. The aim is to dissect the underlying molecular mechanism of microRNA-based gene regulation during pathogen in ....Deciphering the role of microRNAs during pathogen attack: new concepts for disease resistance in plants. Small non-coding RNAs called ‘microRNAs’ regulate diverse pathways in plants including plant defence against pathogens. This project will investigate the roles of plant microRNAs in response to four economically important viruses and compare these to a bacterial and a fungal pathogen. The aim is to dissect the underlying molecular mechanism of microRNA-based gene regulation during pathogen infection and specifically identify common microRNAs which have evident impact during virus attack. This study is crucial due to its focus on virus diseases that cause severe damage to many crop plants; a global issue with strong implications for food security. This project is expected to provide basic new concepts for disease resistance in plants.Read moreRead less
Engineering the defence-vigour balance for increased crop yield. This project aims to investigate a novel hypothesis to increase seed yield and vigour. Translating from a model system it will test whether the deliberate inactivation of a gene in tomato and banana, by RNA interference or genome editing, enhances performance. A dysfunctional gene in the viral defence pathway of the model plant species N. benthamiana boosted its seed yield and vigour. This project will investigate the enhancement, ....Engineering the defence-vigour balance for increased crop yield. This project aims to investigate a novel hypothesis to increase seed yield and vigour. Translating from a model system it will test whether the deliberate inactivation of a gene in tomato and banana, by RNA interference or genome editing, enhances performance. A dysfunctional gene in the viral defence pathway of the model plant species N. benthamiana boosted its seed yield and vigour. This project will investigate the enhancement, determine the consequences to the plant's defences, measure the balance between defence and vigour, and examine the risk of disease to such yield-enhanced crops. This is a radical departure from conventional approaches to crop improvement but if successful would provide an additional solution to the problem of future food security.Read moreRead less
Predicting the delivery of ecosystem services in agricultural landscapes. The ecological sustainability of Australian agriculture relies on services (for example, pollination) provided by ecosystems. Service provision is threatened by environmental change, but there is no established approach for predicting the impact of change on services. This project will undertake the most comprehensive experimental examination of ecosystem-service delivery ever conducted in Australia, testing the predictive ....Predicting the delivery of ecosystem services in agricultural landscapes. The ecological sustainability of Australian agriculture relies on services (for example, pollination) provided by ecosystems. Service provision is threatened by environmental change, but there is no established approach for predicting the impact of change on services. This project will undertake the most comprehensive experimental examination of ecosystem-service delivery ever conducted in Australia, testing the predictive capacity of an approach that links environmental change with variation in service provision through species’ traits. The major outcomes include greater capacity for agriculturalists to maximise ecosystem benefits and increase economic returns, and improved biodiversity conservation through recognition of its contribution to agriculture. Read moreRead less
In situ desalination with membranes for climate resilient irrigation. This project aims to design a climate-resilient irrigation system that minimises evaporative losses and can operate on brackish groundwater without reducing crop yield or damaging soil structure. To do so, it will improve a sub-surface irrigation system that uses desalination membranes. The irrigation system is built on understanding water transport under tension caused by plant transpiration and identifying membranes that can ....In situ desalination with membranes for climate resilient irrigation. This project aims to design a climate-resilient irrigation system that minimises evaporative losses and can operate on brackish groundwater without reducing crop yield or damaging soil structure. To do so, it will improve a sub-surface irrigation system that uses desalination membranes. The irrigation system is built on understanding water transport under tension caused by plant transpiration and identifying membranes that can supply water and remove salt without cativation.Read moreRead less
Plasma-catalytic bubbles for sustainable ammonia. Ammonia is one of the world’s most important chemicals directly sustaining over 50% of our food supply. But the current means of its production is highly eco-destructive and responsible for over 1% of global CO2 emissions, a similar value to global air travel. This project aims to produce ammonia from renewable sources of water, electricity and air, which can provide farmers with a zero-carbon fertilizer under a decentralized and even farm-level ....Plasma-catalytic bubbles for sustainable ammonia. Ammonia is one of the world’s most important chemicals directly sustaining over 50% of our food supply. But the current means of its production is highly eco-destructive and responsible for over 1% of global CO2 emissions, a similar value to global air travel. This project aims to produce ammonia from renewable sources of water, electricity and air, which can provide farmers with a zero-carbon fertilizer under a decentralized and even farm-level approach. Moreover, if driven by renewables, ammonia offers an effective means of exporting hydrogen from Australia. Hydrogen has been highlighted by the federal government as a priority technology in its Technology Investment Roadmap with ammonia seen as the best approach for its exportation. Read moreRead less