Interfacial Barriers to Transport in Nanomaterials. This project aims to make ground-breaking advances in the modelling of transport in disordered nanoporous materials by uncovering the interfacial barriers that are critical to the entry and exit of molecules from their nanostructure. The expected outcome is an efficient new simulation tool to simultaneously quantify interfacial transport resistances and system size-dependent internal transport coefficients. This is intended to be achieved throu ....Interfacial Barriers to Transport in Nanomaterials. This project aims to make ground-breaking advances in the modelling of transport in disordered nanoporous materials by uncovering the interfacial barriers that are critical to the entry and exit of molecules from their nanostructure. The expected outcome is an efficient new simulation tool to simultaneously quantify interfacial transport resistances and system size-dependent internal transport coefficients. This is intended to be achieved through simulations and experiments on the adsorption and dynamics of targeted gases in carbons with distinctly different nanostructures, enabling the optimal design of a wide range of emerging nanotechnologies for membrane separations, kinetic molecular sieving, catalysis, and gas and electrochemical energy storage.Read moreRead less
Engineering floating liquid marbles for three-dimensional cell cultures. This project aims to understand the physics of three-dimensional cell cultures in a liquid marble floating on a liquid free surface. New methodology developed can produce these cell cultures without using matrices or scaffolds and with run-times well beyond existing technologies. This methodology closely mimics a normal in-vivo environment and produces spheroids needed in cell transplantation therapies. This project will re ....Engineering floating liquid marbles for three-dimensional cell cultures. This project aims to understand the physics of three-dimensional cell cultures in a liquid marble floating on a liquid free surface. New methodology developed can produce these cell cultures without using matrices or scaffolds and with run-times well beyond existing technologies. This methodology closely mimics a normal in-vivo environment and produces spheroids needed in cell transplantation therapies. This project will resolve uncertainties in the underlying phenomena. The expected outcome should support future high quality cell cultures suitable for transplantation therapies.Read moreRead less
Relative Permeability in Coal. This project aims to deliver a better model for coal relative permeability to improve the management of coal seam gas reservoirs. Coal relative permeability is a key factor in reservoir models; however, current understanding of relative permeability is wrong for coal systems and predictions based on it are misleading. Relative permeability is currently carried over from conventional gas reservoirs as a function of the degree of water saturation only. This misunders ....Relative Permeability in Coal. This project aims to deliver a better model for coal relative permeability to improve the management of coal seam gas reservoirs. Coal relative permeability is a key factor in reservoir models; however, current understanding of relative permeability is wrong for coal systems and predictions based on it are misleading. Relative permeability is currently carried over from conventional gas reservoirs as a function of the degree of water saturation only. This misunderstands the physical differences between coal and other rocks as gas reservoirs, fails to recognise the determinants of coal relative permeability, and misrepresents the flow system. This project seeks to provide a phenomenologically-based understanding and functional relationship for coal-relative permeability based on the principles than govern physical flow interactions.Read moreRead less
Multi-Scale, Multi-Form Approach to the Modelling, Design and Control of Complex Particulate Processes. Many particulate processes suffer from high recycle rates and instability due to lack of knowledge at various scale levels, and on the fitness between model forms and applications. This project will develop a complete model hierarchy ranging from the microscopic scale to full plant scale using a multi-scale, multi-form approach. The joint force of two world class teams will tackle the complex ....Multi-Scale, Multi-Form Approach to the Modelling, Design and Control of Complex Particulate Processes. Many particulate processes suffer from high recycle rates and instability due to lack of knowledge at various scale levels, and on the fitness between model forms and applications. This project will develop a complete model hierarchy ranging from the microscopic scale to full plant scale using a multi-scale, multi-form approach. The joint force of two world class teams will tackle the complex interaction problems covering granulation fundamentals, dynamic modelling, process design and advanced control. The work will lead to significantly improved productivity and quality for a wide range of industrial particulate processes using innovative design and model based control strategies.Read moreRead less
Improved Nanoscale and Molecular Models for Nanostructured Carbons, and their Applications in Simulation of Confined Fluids. This project has a multitude of benefits for Australia, a key one of which is the promotion of cross-disciplinary interaction and collaboration to conduct leading edge research in a technologically important area. In addition the project will utilize two PhD students who will be trained in research, and gain a broad range of skills in this multifaceted project involving t ....Improved Nanoscale and Molecular Models for Nanostructured Carbons, and their Applications in Simulation of Confined Fluids. This project has a multitude of benefits for Australia, a key one of which is the promotion of cross-disciplinary interaction and collaboration to conduct leading edge research in a technologically important area. In addition the project will utilize two PhD students who will be trained in research, and gain a broad range of skills in this multifaceted project involving theory, simulation and experiment. The research, grounded in molecular fundamentals, will also lead to the development of advanced tools for adsorption process modelling, useful in process design and scale-up, and contribute to Goal 1 of National Priority Area 3: Frontier Technologies for Building and Transforming Australian Industries.Read moreRead less
Multi-component Gas Transport in Deep Coal. The understanding of multi-component gas flow in coal underlies the use, management and optimization of deep coal as an economic resource for methane recovery, CO2 sequestration, pipeline gas storage and underground gasification. This project will develop a predictive reservoir flow model for deep coal behavior under asymmetric, dynamically evolving internal and external stresses, during multi-component gas release or injection. A confluence of new too ....Multi-component Gas Transport in Deep Coal. The understanding of multi-component gas flow in coal underlies the use, management and optimization of deep coal as an economic resource for methane recovery, CO2 sequestration, pipeline gas storage and underground gasification. This project will develop a predictive reservoir flow model for deep coal behavior under asymmetric, dynamically evolving internal and external stresses, during multi-component gas release or injection. A confluence of new tools including a large sample, high pressure, triaxial stress permeameter, and micron resolved 3D reconstruction of the coal cleat and pore structure, will provide physical parameters to the fundamentally based, competitive transport and adsorption/desorption model.Read moreRead less
Anisotropic behaviour of coal for coalbed methane recovery and CO2 geosequestration. Amongst the cheapest and safest options for clean energy are to use natural gas from coal seams for electricity and fuel production and then permanently store carbon dioxide within the depleted seams. This requires information about the underground behaviour of coal at a level of detail which is not available. In particular, the directional and dynamic response of coal to changes in pressure, stress and gas in ....Anisotropic behaviour of coal for coalbed methane recovery and CO2 geosequestration. Amongst the cheapest and safest options for clean energy are to use natural gas from coal seams for electricity and fuel production and then permanently store carbon dioxide within the depleted seams. This requires information about the underground behaviour of coal at a level of detail which is not available. In particular, the directional and dynamic response of coal to changes in pressure, stress and gas interactions is required, which is the subject of this project. Coal bed methane is rapidly growing into a multi-billion dollar industry for Australia. The geosequestration of carbon dioxide in deep coal is widely recognised presenting a secure and economical opportunity for greenhouse gas control. Read moreRead less
Precision-engineered hybrid core-shell materials . This project aims to develop new platform technologies for making nanostructured hybrid core-shell materials with exceptionally high drug loading and programmed release. Building on this research team's recent breakthrough in the precision engineering of core-shell materials, this research will revolutionise current approaches for making drug-loaded polymer and inorganic particles. Significant outcomes will include a novel sequential nanoprecipi ....Precision-engineered hybrid core-shell materials . This project aims to develop new platform technologies for making nanostructured hybrid core-shell materials with exceptionally high drug loading and programmed release. Building on this research team's recent breakthrough in the precision engineering of core-shell materials, this research will revolutionise current approaches for making drug-loaded polymer and inorganic particles. Significant outcomes will include a novel sequential nanoprecipitation platform technology for making drug-core polymer-shell nanoparticles, and a new bio-inspired approach for making hybrid drug-core silica-shell nanocomposites, and new materials for applications in programmed release and delivery systems.Read moreRead less
Friction-based modelling of the dynamics of nanoconfined fluid mixtures. This project will transform the molecular science of fluid transport in nanoconfined spaces by delivering a tool that will be critical to the development of emerging nanotechnologies. The tool will embed a novel theory in a framework for modelling transport over all scales from nano- to macroscopic. The project will have strong benefits for the advancement of leading-edge fundamental research and in its relevance to a numbe ....Friction-based modelling of the dynamics of nanoconfined fluid mixtures. This project will transform the molecular science of fluid transport in nanoconfined spaces by delivering a tool that will be critical to the development of emerging nanotechnologies. The tool will embed a novel theory in a framework for modelling transport over all scales from nano- to macroscopic. The project will have strong benefits for the advancement of leading-edge fundamental research and in its relevance to a number of novel nanotechnologies. It will be particularly relevant to scientific and industrial developments exploiting new nanomaterials such as AlPO4-25, carbon molecular sieves and carbon nanotubes, as well as in nanofluidics.Read moreRead less
Modelling of Adsorption Dynamics in Microporous Solids based on Molecular Dynamics Computations. This project seeks to incorporate non-equilibrium molecular dynamics calculations into particle scale models for adsorption kinetics. Molecular dynamics calculations will be performed for hydrocarbon molecules in small pores to obtain transport coefficients in pores of various sizes, at various bulk gas pressures and temperatures. These transport coefficients will be used in particle scale models t ....Modelling of Adsorption Dynamics in Microporous Solids based on Molecular Dynamics Computations. This project seeks to incorporate non-equilibrium molecular dynamics calculations into particle scale models for adsorption kinetics. Molecular dynamics calculations will be performed for hydrocarbon molecules in small pores to obtain transport coefficients in pores of various sizes, at various bulk gas pressures and temperatures. These transport coefficients will be used in particle scale models to obtain a dynamic model, which will be utilised to interpret experimental data from the literature as well as that being obtained in our laboratory. Such first principles-based modelling has not been performed before at the particle scale, and will mitigate the empiricism in existing approaches.Read moreRead less