Designing and Building Novel 2D Hybrid Materials. The aim of this project is to use computational and experimental techniques to discover and fabricate new hybrid materials. Single-layer (2-D) materials like graphene have gained prominence and new ones are constantly being reported. Hybrid materials built from combinations of 2-D layers are appearing but progress is slow. This project is designed to increase the rate of discovery and fabrication of hybrids. The outcome would be an extensive data ....Designing and Building Novel 2D Hybrid Materials. The aim of this project is to use computational and experimental techniques to discover and fabricate new hybrid materials. Single-layer (2-D) materials like graphene have gained prominence and new ones are constantly being reported. Hybrid materials built from combinations of 2-D layers are appearing but progress is slow. This project is designed to increase the rate of discovery and fabrication of hybrids. The outcome would be an extensive database of materials properties, clear direction on how to control material properties, and manufacturing protocols to build a wide range of new materials.Read moreRead less
Understanding and optimising the microstructure of Germanium-Arsenic-Selenium glasses for superior device performance. The project will seek to use a combined theoretical and experimental approach to develop 'state of the art' optical glass materials for use in integrated nonlinear optical components. Such materials could be used as optical waveguides in broadband communication systems and offer the possibility of significant improvement in telecommunication performance.
A theoretical hierachy to investigate the electronic behaviour of graphene nanostructures under realistic conditions. One of the most exciting new nano-materials is graphene which promises to be the basis of a new industry producing nano-electronics and nano-devices such as chemical sensors. This project aims to provide sound scientific knowledge on the effects of environmental conditions on the properties of graphene which are vital for its industrial use.
Exploiting shear to form new structures of carbon. This project aims to create new, technologically-interesting, materials by combining shear (sliding forces) with high pressure. The work will use both modelling and experiments to understand the pathways to form new materials such as a different form of diamond that is predicted to be harder than regular diamond. Such a material could be used in coatings for cutting tools or ultra-low-scratch surfaces. Expected outcomes include both an understan ....Exploiting shear to form new structures of carbon. This project aims to create new, technologically-interesting, materials by combining shear (sliding forces) with high pressure. The work will use both modelling and experiments to understand the pathways to form new materials such as a different form of diamond that is predicted to be harder than regular diamond. Such a material could be used in coatings for cutting tools or ultra-low-scratch surfaces. Expected outcomes include both an understanding of the importance of shear in the study of high-pressure science, and as a tool to manufacture new functional materials.Read moreRead less
Generalised density functional theory for accurate chemistry. The project aims to construct two new methods for predicting chemical structure, bonding and reactivity. The first of these (gLDA2) would be useful for modelling molecules whose electrons are constrained to a two-dimensional plane. The second (gLDA3) would be useful for modelling molecules with unconstrained electrons. The project plans to implement the two methods in user-friendly software packages and made available to researchers i ....Generalised density functional theory for accurate chemistry. The project aims to construct two new methods for predicting chemical structure, bonding and reactivity. The first of these (gLDA2) would be useful for modelling molecules whose electrons are constrained to a two-dimensional plane. The second (gLDA3) would be useful for modelling molecules with unconstrained electrons. The project plans to implement the two methods in user-friendly software packages and made available to researchers in Australia and around the world improve manufacturing efficiency in the chemical, biological, medicinal and agricultural contexts. Unlike the semi-empirical approaches that they seek to replace, these two new methods will be derived from the properties of electrons on spheres or hyperspheres and thereby have a solid foundation in quantum mechanics.Read moreRead less
Synchrotron X-ray absorption fine structure and fundamental X-ray interactions for nano-physics, chemistry and mineralogy. This project will develop new synchrotron techniques for measuring and interpreting X-ray data from materials targeting the nano-environment and bonding. The first wave of synchrotron nanotechnology is nascent. The project's X-ray methods develop techniques in applied mineralogy and catalysis. New insight will address key questions in chemistry, mining and biology.