Plasma-soft tissue interactions: advancing a new era of plasma technologies. This project aims to develop the prerequisite knowledge to underpin new plasma technologies. Specifically, the project plans to provide new insight into the interaction between ionised gas plasma jets and biological soft tissue. It plans to use advanced analytical techniques and modelling simulations to investigate the physics of the plasma jet and processes occurring at the jet–tissue interface. It also plans to use (b ....Plasma-soft tissue interactions: advancing a new era of plasma technologies. This project aims to develop the prerequisite knowledge to underpin new plasma technologies. Specifically, the project plans to provide new insight into the interaction between ionised gas plasma jets and biological soft tissue. It plans to use advanced analytical techniques and modelling simulations to investigate the physics of the plasma jet and processes occurring at the jet–tissue interface. It also plans to use (bio)engineered tissue targets, chemical, biological and cellular assays to probe the transport and effects of plasma reactive species deep within tissue. This new knowledge would enable the development of new plasma sources and protocols for applications in health, medicine, biotechnology and manufacturing.Read moreRead less
A universally efficient antibacterial coating with remarkable durability. To prevent the spread of diseases and infections through contaminated surfaces, the project intends to create new ceramic-based coatings that combine mechanical durability with broad-spectrum antibacterial activities. Around 200 000 infections, many fatal, occur in Australian hospitals each year, with contaminated surfaces being a primary source. To combat this challenge, the project aims to develop a new class of ceramic- ....A universally efficient antibacterial coating with remarkable durability. To prevent the spread of diseases and infections through contaminated surfaces, the project intends to create new ceramic-based coatings that combine mechanical durability with broad-spectrum antibacterial activities. Around 200 000 infections, many fatal, occur in Australian hospitals each year, with contaminated surfaces being a primary source. To combat this challenge, the project aims to develop a new class of ceramic-based coatings, which are extremely robust yet highly effective in eliminating common and emerging bacteria, by uniting new antibacterial agents into a self-toughening micro-architecture. By disrupting bacterial transmission through surfaces, this project promises to protect the wellbeing of patients and healthcare professionals, and to help maintain food and water safety standards in Australia.Read moreRead less
Designed to last: novel gradient coatings for extreme environments. Hard coatings are frequently applied to equipment operating in harsh environments. Often such coatings are highly brittle and so fragile under stress, especially at high temperatures or in corrosive environments. Premature failure can affect safety and lead to negative economic and environmental consequences. The objective of this project is to combine bioinspired microstructural design with an emerging alloying concept to produ ....Designed to last: novel gradient coatings for extreme environments. Hard coatings are frequently applied to equipment operating in harsh environments. Often such coatings are highly brittle and so fragile under stress, especially at high temperatures or in corrosive environments. Premature failure can affect safety and lead to negative economic and environmental consequences. The objective of this project is to combine bioinspired microstructural design with an emerging alloying concept to produce a breakthrough in the development of engineering coatings; for example, overcoming the long standing trade-off between hardness and toughness. Such an innovative coating is expected to be highly durable in extreme conditions, and in so doing will help transform manufacturing, mining and desalination industries.Read moreRead less