Development of high-performance lead-free piezoelectric superlattices for environmentally-friendly and biocompatible piezoelectric micromachined ultrasonic transducers (pMUTs) applications. This program is aimed at development of environmentally friendly and biocompatible lead-free piezoelectric thin films and superlattices for the potential applications in pMUTs. The expected outcome includes deposition of BNT and BZT-based thin films and superlattices, and enhancement of their physical propert ....Development of high-performance lead-free piezoelectric superlattices for environmentally-friendly and biocompatible piezoelectric micromachined ultrasonic transducers (pMUTs) applications. This program is aimed at development of environmentally friendly and biocompatible lead-free piezoelectric thin films and superlattices for the potential applications in pMUTs. The expected outcome includes deposition of BNT and BZT-based thin films and superlattices, and enhancement of their physical properties by strain and interface engineering.Read moreRead less
Photoelectrocatalysis-based Techniques for Bactericidal Applications. Effective control of the quality of water supply is paramount for public health. This project aims to develop a novel photoelectrocatalysis (PEC) based bactericidal technology capable of instant inactivation and rapid decomposition of waterborne pathogens in recycled water. The PEC processes at the illuminated semiconductor photoanodes with ultraviolet (UV) and visible light activities will be innovatively utilised with the ai ....Photoelectrocatalysis-based Techniques for Bactericidal Applications. Effective control of the quality of water supply is paramount for public health. This project aims to develop a novel photoelectrocatalysis (PEC) based bactericidal technology capable of instant inactivation and rapid decomposition of waterborne pathogens in recycled water. The PEC processes at the illuminated semiconductor photoanodes with ultraviolet (UV) and visible light activities will be innovatively utilised with the aim of in-situ generation of stable di-halide radical anions, reactive oxygen species and photoholes as effectual bactericides to achieve instant inactivation and rapid decomposition of waterborne pathogens. The success of the project is expected to provide Australian water industry with enabling technology to safeguard recycled water usage.Read moreRead less