Seeing the discrete in a continuum: an integrated numerical-rheological-experimental approach towards high resolution micromechanical continuum models of granular media. Processes involving granular materials are complex and rarely reach more than 60% of the design capacity, due to inadequate understanding of granular rheology. The short term benefits of the proposed project are: improved insights on the rheology of granular media; experimentally validated micromechanical constitutive models ....Seeing the discrete in a continuum: an integrated numerical-rheological-experimental approach towards high resolution micromechanical continuum models of granular media. Processes involving granular materials are complex and rarely reach more than 60% of the design capacity, due to inadequate understanding of granular rheology. The short term benefits of the proposed project are: improved insights on the rheology of granular media; experimentally validated micromechanical constitutive models with unmatched predictive capabilities; modelling techniques in the analysis of multiscale processes, germane to the Science of Complex Materials. The long term benefits are models of the required reliability for computer-aided design, production and management of particulate systems. These simulation tools will enhance Australia's competitive edge in the multi-billion dollar particulate and geotechnical industries.Read moreRead less
Modelling and simulation of emergent behaviour in particulate assemblies under terrestrial and microgravity conditions: a focus on force propagation. Systems and processes involving particulate matter are complex, and due to inadequate understanding and modelling capabilities, rarely reach more than 60% of the design capacity. Given the prominence of these materials in Australia's leading export industries, the potential economic and social impact of this research program is significant. For exa ....Modelling and simulation of emergent behaviour in particulate assemblies under terrestrial and microgravity conditions: a focus on force propagation. Systems and processes involving particulate matter are complex, and due to inadequate understanding and modelling capabilities, rarely reach more than 60% of the design capacity. Given the prominence of these materials in Australia's leading export industries, the potential economic and social impact of this research program is significant. For example, Australia holds the largest known resources of iron ore with annual exports exceeding $3.8 billion; annual wheat exports exceed $3.4 billion and 90% of Australia's sealed roads (granular paved) cost $1 billion per year to maintain. This research will advance knowledge of fundamental behaviour and deliver predictive tools to control and optimise processes involving particulate matter.Read moreRead less
Mathematical and mechanical modeling of nano particulate flow. Nano particulates are the basis for many new technologies, including coatings in the electronics industry, composite materials and medical and pharmaceutical applications. Worldwide industrial competition is increasingly determined by our capacity to handle such highly cohesive materials, and to exploit their novel physical, chemical and mechanical characteristics. Devising handling mechanisms and understanding nano particulate flows ....Mathematical and mechanical modeling of nano particulate flow. Nano particulates are the basis for many new technologies, including coatings in the electronics industry, composite materials and medical and pharmaceutical applications. Worldwide industrial competition is increasingly determined by our capacity to handle such highly cohesive materials, and to exploit their novel physical, chemical and mechanical characteristics. Devising handling mechanisms and understanding nano particulate flows depends on formulating accurate mathematical models which reflect the correct underlying physics. This APF proposal will utilise advanced continuum mechanics to develop the correct underlying conceptual ideas to resolve fundamental nanomechanical particulate flows, which will lead to the next generation of engineering tools.
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