A Novel Multilevel Modelling Framework to Design Diamond Nanothread Bundles. This project aims to develop a novel, computationally-based framework to optimally and efficiently design new fibre materials based on the diamond nanothreads synthesized by the PI in 2014. The CIs (and others) have demonstrated the tremendous promise these materials hold to replace common carbon fibres. The proposed framework will combine advanced computer modelling, statistical learning, genetic algorithm-based optima ....A Novel Multilevel Modelling Framework to Design Diamond Nanothread Bundles. This project aims to develop a novel, computationally-based framework to optimally and efficiently design new fibre materials based on the diamond nanothreads synthesized by the PI in 2014. The CIs (and others) have demonstrated the tremendous promise these materials hold to replace common carbon fibres. The proposed framework will combine advanced computer modelling, statistical learning, genetic algorithm-based optimal design and experimental validations. It will accelerate the design of these new carbon-based fibres as game-changing materials in a wide range of areas. Ultimately this project has the potential to deliver significant economic benefits and will place Australia at the forefront of the industrial revolution of the future.Read moreRead less
Dislocation motion and anelastic recovery in layered ceramic titanate. This project aims to research deformation and facture in brittle ceramic nanowire materials and anelastic behaviour in tensile deformation. Layered sodium titanate is used in energy storage and water treatment, but in-situ tensile tests have observed unconventional deformation behaviour, with significant dislocation motion and anelastic recovery. This project will study the deformation mechanism in layered sodium titanate nan ....Dislocation motion and anelastic recovery in layered ceramic titanate. This project aims to research deformation and facture in brittle ceramic nanowire materials and anelastic behaviour in tensile deformation. Layered sodium titanate is used in energy storage and water treatment, but in-situ tensile tests have observed unconventional deformation behaviour, with significant dislocation motion and anelastic recovery. This project will study the deformation mechanism in layered sodium titanate nanowires through molecular dynamics simulations, empirical interatomic potential, and in situ TEM experiments. Expected outcomes include knowledge of the deformation mechanism of this layered titanate which can be broadened to technologically important layered ceramic materials.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190101152
Funder
Australian Research Council
Funding Amount
$404,000.00
Summary
Micro/nano-mechanical testing methodologies for interfacial adhesion. This project aims to develop reliable approaches for measuring the toughness of a variety of metal/polymer interfaces integral to contemporary flexible devices. Adhesion between metal thin film conductors and polymer substrates is a critical factor influencing the reliability of the emerging polymer-based flexible electronics. This project will develop new methodologies for understanding the behaviour of these metal/polymer in ....Micro/nano-mechanical testing methodologies for interfacial adhesion. This project aims to develop reliable approaches for measuring the toughness of a variety of metal/polymer interfaces integral to contemporary flexible devices. Adhesion between metal thin film conductors and polymer substrates is a critical factor influencing the reliability of the emerging polymer-based flexible electronics. This project will develop new methodologies for understanding the behaviour of these metal/polymer interfaces. This project will be a crucial enabler to accelerating the development of new flexible microelectronic technologies, from solar panels to electronic skin. This innovation will enable Australia to maintain an important connection to the rapidly-evolving international microelectronic industry and add significant value to Australian manufacturing industries.Read moreRead less
Developing innovative methodologies to understand nano-adhesion/friction. The project seeks to improve the measurement of nanoscale adhesion and friction. The understanding of adhesion and friction between a nanowhisker and a substrate is crucial for developing next-generation nanodevices. However, the current methods for measuring nanoscale adhesion and friction are inaccurate and can produce contradictory results, due to the extreme challenges in mastering sophisticated measuring techniques an ....Developing innovative methodologies to understand nano-adhesion/friction. The project seeks to improve the measurement of nanoscale adhesion and friction. The understanding of adhesion and friction between a nanowhisker and a substrate is crucial for developing next-generation nanodevices. However, the current methods for measuring nanoscale adhesion and friction are inaccurate and can produce contradictory results, due to the extreme challenges in mastering sophisticated measuring techniques and the lack of understanding of their underlying mechanisms. This project aims to develop innovative ‘push-peel’ and ‘push-slide’ methods to accurately measure those properties and to further understand their fundamental origins. Successful outcomes from this study would not only solve a long-standing problem in the application of nanowhiskers, but also generate new nanosurface science.Read moreRead less