Controllable synthesis of multifunctional boron-based 2D materials. This project aims to make it possible to control the synthesis of boron-based two-dimensional (2D) materials with the desired following features in single or multiple aspects: thickness, composition, lateral sizes, porosity, surface area, and functionality. It intends to do so by designing and synthesising novel precursors, and by optimising the fabrication process of boron-based 2D nanosheets for different applications. The pro ....Controllable synthesis of multifunctional boron-based 2D materials. This project aims to make it possible to control the synthesis of boron-based two-dimensional (2D) materials with the desired following features in single or multiple aspects: thickness, composition, lateral sizes, porosity, surface area, and functionality. It intends to do so by designing and synthesising novel precursors, and by optimising the fabrication process of boron-based 2D nanosheets for different applications. The project will advance our fundamental knowledge in synthetic chemistry, materials chemistry, materials engineering and physics. It is expected to take us closer to unlocking the potential of boron-based 2D materials for real-world applications in, for example, energy storage and high-performance flexible electronics.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100215
Funder
Australian Research Council
Funding Amount
$368,446.00
Summary
Nature-inspired electrochemical conversion of nitrogen to ammonia. This project aims to achieve a highly active electrochemical catalytic system for ammonia production from atmospheric nitrogen under ambient conditions. Ammonia is essential for plant growth and food production but its synthesis is energy intensive, eco-destructive and costly. The project will design a functional device featuring a catalyst that will not only provide insights into the fundamentals of nitrogen reduction but also a ....Nature-inspired electrochemical conversion of nitrogen to ammonia. This project aims to achieve a highly active electrochemical catalytic system for ammonia production from atmospheric nitrogen under ambient conditions. Ammonia is essential for plant growth and food production but its synthesis is energy intensive, eco-destructive and costly. The project will design a functional device featuring a catalyst that will not only provide insights into the fundamentals of nitrogen reduction but also a sustainable and cost effective production of ammonia, a potential key to future world food supply and renewable energy.Read moreRead less