Discovery Early Career Researcher Award - Grant ID: DE230101105
Funder
Australian Research Council
Funding Amount
$422,318.00
Summary
Developing Polymer Electrolytes for Operational All-Solid-State Batteries. This project aims to advance the development of safe rechargeable all-solid-state batteries (ASSBs) by innovating fluorinated block copolymers as solid-state electrolytes. ASSBs are the most promising power source for emerging energy storage goals, however, low ionic conductivity and poor long-term cycling stability are critical bottlenecks to their successful application. This project seeks to tackle these challenges by ....Developing Polymer Electrolytes for Operational All-Solid-State Batteries. This project aims to advance the development of safe rechargeable all-solid-state batteries (ASSBs) by innovating fluorinated block copolymers as solid-state electrolytes. ASSBs are the most promising power source for emerging energy storage goals, however, low ionic conductivity and poor long-term cycling stability are critical bottlenecks to their successful application. This project seeks to tackle these challenges by fabricating unique ionic conduction channels and stabilising electrode-electrolyte interfaces using fluorinated block copolymer electrolytes. The expected outcomes are new knowledge in polymer electrolytes and advancement in the commercialisation of ASSBs toward more efficient, safe and reliable energy storage technologies.Read moreRead less
A platform technology for developing mesoporous polymer particles. This project aims to apply polymerisation-induced self-assembly process to develop triggerable mesoporous polymer particles as advanced functional materials for various applications. By combining this scalable process and automated synthesis technique, mesoporous polymer particles that can disassemble in response to external triggers, such as light, redox conditions and enzymes, will be developed. The knowledge gained from this r ....A platform technology for developing mesoporous polymer particles. This project aims to apply polymerisation-induced self-assembly process to develop triggerable mesoporous polymer particles as advanced functional materials for various applications. By combining this scalable process and automated synthesis technique, mesoporous polymer particles that can disassemble in response to external triggers, such as light, redox conditions and enzymes, will be developed. The knowledge gained from this research will allow researchers to fully understand the formation and evolution mechanism of inverse bicontinuous structures observed in nature and produced in synthetic labs. Importantly, the applications of these novel stimuli-responsive particles as nano-carriers and templating scaffolds will be investigated.Read moreRead less