High productivity of hybrid plasma electrocatalytic fertiliser production. Non-thermal plasma-driven electrocatalytic production of nitrogen fertilisers. The project aims to develop scalable technology for ambient production of fertilisers using renewable energy, air, water, and captured CO2. This project is anticipated to generate new knowledge in plasma catalysis and electrochemical coupling through designing and fine-tuning catalyst-loaded 3D scaffolds. Expected outcomes of this project inclu ....High productivity of hybrid plasma electrocatalytic fertiliser production. Non-thermal plasma-driven electrocatalytic production of nitrogen fertilisers. The project aims to develop scalable technology for ambient production of fertilisers using renewable energy, air, water, and captured CO2. This project is anticipated to generate new knowledge in plasma catalysis and electrochemical coupling through designing and fine-tuning catalyst-loaded 3D scaffolds. Expected outcomes of this project include increasing the capacity to adopt low-cost and decentralised methods for renewable energy utilisation. This should provide substantial technological capacity that can be applied to other sectors of Australia's developing hydrogen economy and expand the use of renewable energy Power-to-X for zero-emissions energy vectors.Read moreRead less
Plasma driven electrochemical synthesis of urea. Urea is the most used nitrogen fertilizer in the world, with more urea manufactured by mass than any other organic chemical. However, the world is experiencing a major shortage of the compound, impacting our food costs and security along with dependent products such as AdBlue (diesel exhaust fluid). Commercial urea production relies on a complex reaction between ammonia and carbon dioxide at high temperatures, which consumes more than 2% of the w ....Plasma driven electrochemical synthesis of urea. Urea is the most used nitrogen fertilizer in the world, with more urea manufactured by mass than any other organic chemical. However, the world is experiencing a major shortage of the compound, impacting our food costs and security along with dependent products such as AdBlue (diesel exhaust fluid). Commercial urea production relies on a complex reaction between ammonia and carbon dioxide at high temperatures, which consumes more than 2% of the world’s energy. This project aims to produce more sustainable urea driven by electricity and using air and captured CO2, through the use of a plasma-driven electrochemical technology, providing farmers with a low-cost fertilizer under a decentralized and secure supply. Read moreRead less
Australian clays as raw materials of slow-release phosphate fertiliser. Phosphorus (P) fertiliser input in Australia is a significant problem for its inefficient plant uptake, leaching to natural water bodies and stocking of insoluble P in soil. The project aims to develop activated clays using Australian raw clay minerals to formulate effective slow-release phosphate (P) fertilisers (SRF) and delivery material for P-solubilising bacteria. Composite of these will supply P controllably even amid ....Australian clays as raw materials of slow-release phosphate fertiliser. Phosphorus (P) fertiliser input in Australia is a significant problem for its inefficient plant uptake, leaching to natural water bodies and stocking of insoluble P in soil. The project aims to develop activated clays using Australian raw clay minerals to formulate effective slow-release phosphate (P) fertilisers (SRF) and delivery material for P-solubilising bacteria. Composite of these will supply P controllably even amid environmental fluctuations but when a plant needs as it grows. Development of multifunctional, nontoxic and plant growth-driven P fertiliser would benefit improve soil fertility in a sustainable way where efficiency of P input is maximised with a minimised environmental burden.Read moreRead less