AM of MAX Phase parts for applications in extreme environments. This project aims to develop techniques to synthesize MAX Phase compound materials in-situ using laser additive manufacturing. The project expects to increase jet engine fuel efficiency and thrust, and to fabricate longer-lasting parts for supersonic speed applications. The expected outcomes include well-developed additive manufacturing processes to make high performance engineering components with shape complexity for extreme envir ....AM of MAX Phase parts for applications in extreme environments. This project aims to develop techniques to synthesize MAX Phase compound materials in-situ using laser additive manufacturing. The project expects to increase jet engine fuel efficiency and thrust, and to fabricate longer-lasting parts for supersonic speed applications. The expected outcomes include well-developed additive manufacturing processes to make high performance engineering components with shape complexity for extreme environment applications, and new methods to increase the 3D printability of brittle materials. This should provide significant benefits to aerospace and defense industries through solving their long standing bottleneck material and processing problems. The outcomes also enhance Australia’s manufacturing capacity.Read moreRead less
Low-cost, Lightweight and Liquid Helium-free Superconducting MRI Magnet. This project aims to develop a liquid-helium-free superconducting technology to address the need for more affordable MRI magnets that currently rely on expensive, limited supplies of liquid helium. This project expects to generate a world-first, much needed MRI systems to be operated in persistent mode without a power supply, to obtain high-resolution images and low-cost operation. The expected outcomes include a novel, lig ....Low-cost, Lightweight and Liquid Helium-free Superconducting MRI Magnet. This project aims to develop a liquid-helium-free superconducting technology to address the need for more affordable MRI magnets that currently rely on expensive, limited supplies of liquid helium. This project expects to generate a world-first, much needed MRI systems to be operated in persistent mode without a power supply, to obtain high-resolution images and low-cost operation. The expected outcomes include a novel, lightweight, easy-to-operate magnesium diboride superconducting MRI magnet prototype under persistent mode operation. This should provide significant benefits, including reducing the cost associated with conventional liquid helium-dependent technologies and ensuring Australia at the forefront of MRI development worldwide.Read moreRead less
A next generation 'smart' superconducting magnet system in persistent mode. Superconducting magnet devices use splicing, a process required to maintain the persistence of operation. Currently, the formation mechanism of splicing using magnesium diboride superconductor is complex and not technologically robust for industrial magnet manufacturing. This project aims to develop novel, reliable and economical superconducting splicing technologies that can produce an ultra-stable and uniform magnetic ....A next generation 'smart' superconducting magnet system in persistent mode. Superconducting magnet devices use splicing, a process required to maintain the persistence of operation. Currently, the formation mechanism of splicing using magnesium diboride superconductor is complex and not technologically robust for industrial magnet manufacturing. This project aims to develop novel, reliable and economical superconducting splicing technologies that can produce an ultra-stable and uniform magnetic field against unexpected power outages. Expected outcomes include the development of advanced green and cryogen free superconducting technologies, which would boost the Australian manufacturing industry through access to multi-billion-dollar global markets for power grids, medical imaging and energy generation and storage.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100975
Funder
Australian Research Council
Funding Amount
$415,775.00
Summary
Architectured ceramics to combine strength, toughness, and complex shapes. This project aims to develop ceramics that are simultaneously strong and tough, and to form them into complex shapes without compromising their mechanical properties – major challenges in science and engineering. Inspired by the internal architectures that confer these advantages on natural hard materials, it will produce novel ceramics with rationally-designed, highly-controlled dense architectures by developing a fast, ....Architectured ceramics to combine strength, toughness, and complex shapes. This project aims to develop ceramics that are simultaneously strong and tough, and to form them into complex shapes without compromising their mechanical properties – major challenges in science and engineering. Inspired by the internal architectures that confer these advantages on natural hard materials, it will produce novel ceramics with rationally-designed, highly-controlled dense architectures by developing a fast, scalable and versatile light-based 3D–4D printing technique combined with discrete element modelling. Outcomes will be toughened ceramics and new knowledge on processing-architecture-performance relationships, with significant benefits for biomaterials, defence, transport, high-temperature and aerospace applications.Read moreRead less