All-Metal Nanoporous Materials as Highly Active Electrocatalysts. This project aims to create new avenues for well-controlled large-scale synthesis of hierarchical nanoporous platinum-based architectures, and develop applications for the resultant new electrocatalysts. Developing novel high-performance, low-cost, and long-life electrode catalysts can improve the efficiency, cost, and durability of energy conversion technology. The project plans to use the unique properties of well-defined nanoar ....All-Metal Nanoporous Materials as Highly Active Electrocatalysts. This project aims to create new avenues for well-controlled large-scale synthesis of hierarchical nanoporous platinum-based architectures, and develop applications for the resultant new electrocatalysts. Developing novel high-performance, low-cost, and long-life electrode catalysts can improve the efficiency, cost, and durability of energy conversion technology. The project plans to use the unique properties of well-defined nanoarchitectures to reduce platinum content and to improve electrocatalytic performance. Nanoporous systems in electrocatalysts can provide more active sites and effective surface permeability, which should enhance catalytic activity. Project outcomes may also contribute to our understanding of the relationships among morphologies, pore structures, surface atomic structures and catalytic activities to guide the development of other kinds of high performance nanoporous catalysts.Read moreRead less
Quantum dot-sensitised solar cells: can efficiency beyond the Shockley-Queisser limit be achieved? The project will address key barriers to broader commercialisation of cost-effective titania-based solar cells by utilising novel physics of semiconductor quantum dot materials used as a sensitiser. The research outcomes will answer key questions about the ultimate efficiency of these cells, and help transform the Australian PV industry.
Engineering the Building Blocks of Novel Interfacial Metastable Oxide Materials. This project aims to engineer the building blocks of a new family of materials recently discovered and patented as interfacial metastable oxide (i-MOx). A key discovery is the interfacial columnar atom alignment adjacent to crystal structures, conferring the materials exceptional ionic conduction well beyond the state-of-the-art, with a broad appeal to ionic transport membranes, electrodes in fuel cells and thermal ....Engineering the Building Blocks of Novel Interfacial Metastable Oxide Materials. This project aims to engineer the building blocks of a new family of materials recently discovered and patented as interfacial metastable oxide (i-MOx). A key discovery is the interfacial columnar atom alignment adjacent to crystal structures, conferring the materials exceptional ionic conduction well beyond the state-of-the-art, with a broad appeal to ionic transport membranes, electrodes in fuel cells and thermal cycling oxygen production. Advanced characterisation techniques will be employed to fundamentally elucidate the role that the interfacial structure plays to deliver remarkable performance. The outcomes will lead to possible breakthroughs in advanced materials for emerging green energy applications.Read moreRead less
Addressing Challenges for the Future Grids – Harmonics Standardization. The main aim of this project is to deliver appropriate frequency standardisation to protect electricity grids and support the use of renewable energy sources. Globally, there is no harmonic standardisation within the frequency range of 2–150 kHz, which can significantly affect the reliability of electricity networks and smart grids. Electricity networks are increasingly using renewable energy sources and an efficient loads a ....Addressing Challenges for the Future Grids – Harmonics Standardization. The main aim of this project is to deliver appropriate frequency standardisation to protect electricity grids and support the use of renewable energy sources. Globally, there is no harmonic standardisation within the frequency range of 2–150 kHz, which can significantly affect the reliability of electricity networks and smart grids. Electricity networks are increasingly using renewable energy sources and an efficient loads approach based on power electronics technology. However, this can affect grid reliability and robustness. The project aims to develop advanced tools to better understand the power quality issues of Australian residential, commercial and industrial distribution networks. It also aims to develop novel techniques to improve power quality and reliability of the grids, and to develop harmonics emission and immunity levels to modify the Australian standards accordingly.Read moreRead less