Multi-Group Stochastic Modelling of Population Balance for Gas-Liquid Flows. Multiphase flow systems are encountered in many process industries such as chemical, petroleum, mining, nuclear, energy, food and pharmaceutical, which are fundamental to the Australian economy. Commercially available computer codes for simulating such systems are currently widely used in many Australian industrial sectors. This research project will address the prevalent deficiency in many of these computer codes and ....Multi-Group Stochastic Modelling of Population Balance for Gas-Liquid Flows. Multiphase flow systems are encountered in many process industries such as chemical, petroleum, mining, nuclear, energy, food and pharmaceutical, which are fundamental to the Australian economy. Commercially available computer codes for simulating such systems are currently widely used in many Australian industrial sectors. This research project will address the prevalent deficiency in many of these computer codes and develop new models capable of predicting a wide range of industrial bubbly flow problems. The resultant improved computer codes will provide industries with significant benefits and, in particular, reduce times and costs in their design and production. Read moreRead less
Unique Chemistry from Radioactive Decay in the Solid-State. Australia is an important member of the international nuclear fuel cycle. It holds one-third of the world's uranium reserves and is a major player in the development of technology for immobilizing radioactive waste. We will use computer simulation to answer a very important question which is extremely difficult to study experimentally: How does radioactive decay inside a solid change the chemistry of the material over time? Not only wil ....Unique Chemistry from Radioactive Decay in the Solid-State. Australia is an important member of the international nuclear fuel cycle. It holds one-third of the world's uranium reserves and is a major player in the development of technology for immobilizing radioactive waste. We will use computer simulation to answer a very important question which is extremely difficult to study experimentally: How does radioactive decay inside a solid change the chemistry of the material over time? Not only will our study improve nuclear waste storage, it will also reveal how in-situ chemical change creates new kinds of solids which cannot be made by conventional means. These solids can exhibit unusual and useful behaviour; this project provides the first investigation of this unexplored technological niche.Read moreRead less