Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882926
Funder
Australian Research Council
Funding Amount
$100,000.00
Summary
Transmission Electron Microscope-Nanoindenter for Nano-Mechanical Testing. A transmission electron microscope (TEM)-nanoindenter enables us to record simultaneously the mechanical behaviour of materials under force and their structures and structural evolutions at sub-nanometre resolution. The acquisition of a TEM-nanoindenter will significantly enhance the capability of investigating the structural effect on the behaviour of materials under applied force, which is a key issue in materials scien ....Transmission Electron Microscope-Nanoindenter for Nano-Mechanical Testing. A transmission electron microscope (TEM)-nanoindenter enables us to record simultaneously the mechanical behaviour of materials under force and their structures and structural evolutions at sub-nanometre resolution. The acquisition of a TEM-nanoindenter will significantly enhance the capability of investigating the structural effect on the behaviour of materials under applied force, which is a key issue in materials science and engineering. The results obtained using the TEM-nanoindenter will reveal the fundamental origins of materials mechanical properties and will be used to improve materials processing procedures and to guide the design of stronger and lighter materials for structural applications.Read moreRead less
Ion Implanted Polymers as New Plastic Electronic and Superconducting Materials. A current focus of the electronics industry is developing electronic circuitry and devices on plastic. Such 'soft electronics' offer significant benefits over conventional 'hard' electronics including low cost large-scale production, mechanical flexibility and chemical versatility. We recently discovered that plastic electronic and superconducting materials could be created using a process called ion implantation. ....Ion Implanted Polymers as New Plastic Electronic and Superconducting Materials. A current focus of the electronics industry is developing electronic circuitry and devices on plastic. Such 'soft electronics' offer significant benefits over conventional 'hard' electronics including low cost large-scale production, mechanical flexibility and chemical versatility. We recently discovered that plastic electronic and superconducting materials could be created using a process called ion implantation. This project aims to develop these new materials for potential applications including plastic superconducting electronics, low-cost lightweight plastic circuitry for use with other organic/inorganic electronic materials and electrodes for interfacing with biological systems to create biosensors and biomolecular electronics.Read moreRead less
Nanofabrication of Organic (Plastic) Semiconductor and Superconductor Devices. Organic crystals and thin-films are the first known materials to display all four regimes of electrical conduction - insulator, semiconductor, metal and superconductor. Additional properties such as self-assembly, biocompatibility, molecular level control over properties and flexibility give them exceptional prospects for future industrial applications. We will fabricate organic transistors and conduct detailed invest ....Nanofabrication of Organic (Plastic) Semiconductor and Superconductor Devices. Organic crystals and thin-films are the first known materials to display all four regimes of electrical conduction - insulator, semiconductor, metal and superconductor. Additional properties such as self-assembly, biocompatibility, molecular level control over properties and flexibility give them exceptional prospects for future industrial applications. We will fabricate organic transistors and conduct detailed investigations of their electrical and magnetic properties to develop a fundamental understanding of these new materials. Most significantly, we will make the first use of an atomic force microscope-based oxidation lithography technique to fabricate nanoscale quantum devices that exploit the full range of conduction in a single material.Read moreRead less