Unlocking the ion selectivity of lithium superionic conductor membranes. This project aims to address a longstanding challenge in designing advanced membranes to enable sustainable lithium refining by unlocking the ion selectivity of lithium superionic conductors. This project expects to generate new knowledge in the areas of membrane science and emerging nanoionics by using interdisciplinary approaches. Expected outcomes of this project include a novel class of lithium separation membranes and ....Unlocking the ion selectivity of lithium superionic conductor membranes. This project aims to address a longstanding challenge in designing advanced membranes to enable sustainable lithium refining by unlocking the ion selectivity of lithium superionic conductors. This project expects to generate new knowledge in the areas of membrane science and emerging nanoionics by using interdisciplinary approaches. Expected outcomes of this project include a novel class of lithium separation membranes and their fabrication techniques. This should provide significant benefits in improving lithium extraction and recycling efficiency, reducing their environmental impact and building the research capacity in advanced membrane manufacturing and critical mineral refining in Australia. Read moreRead less
Design of Nanoporous BCN with Tunable Pores for CO2 Capture and Conversion. This project aims to design and develop advanced boron carbon nitride-based materials with high specific surface areas, tunable pores and functional groups, guided by theoretical calculations for the capture of CO2 at ambient conditions. By introducing single metal atoms in the above nanostructures, we also aim to design a novel catalytic system for the effective conversion of CO2 into fine chemicals. This project will o ....Design of Nanoporous BCN with Tunable Pores for CO2 Capture and Conversion. This project aims to design and develop advanced boron carbon nitride-based materials with high specific surface areas, tunable pores and functional groups, guided by theoretical calculations for the capture of CO2 at ambient conditions. By introducing single metal atoms in the above nanostructures, we also aim to design a novel catalytic system for the effective conversion of CO2 into fine chemicals. This project will offer new knowledge on the design of low-cost advanced materials with specific functionalities for the simultaneous capture and conversion of CO2. This project will make a significant impact on Australian industries and further offer job opportunities and economic benefits by offering new technologies for a clean environment.Read moreRead less