Towards Robust Hydrogen Electrode for High-Rate Alkaline Electrolysis. This project aims to develop robust, efficient porous hybrid hydrogen electrodes for electrochemical hydrogen production in anion exchange membrane water electrolyser. anion exchange membrane water electrolyser powered by renewable energy has emerged as a key avenue towards clean hydrogen with zero carbon footprint. However, the electrochemical turnover on the hydrogen electrode has been significantly hindered by the sluggish ....Towards Robust Hydrogen Electrode for High-Rate Alkaline Electrolysis. This project aims to develop robust, efficient porous hybrid hydrogen electrodes for electrochemical hydrogen production in anion exchange membrane water electrolyser. anion exchange membrane water electrolyser powered by renewable energy has emerged as a key avenue towards clean hydrogen with zero carbon footprint. However, the electrochemical turnover on the hydrogen electrode has been significantly hindered by the sluggish reaction kinetics in alkaline solution. The project is expected to generate cost-effective hydrogen electrodes for hydrogen electrolyzers, advanced knowledge in the electrode material engineering, electrochemical reaction mechanistic insights, and eventually promoted development of disruptive electrolysis technology.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240101090
Funder
Australian Research Council
Funding Amount
$433,217.00
Summary
In-depth Investigation of Lithium Dendrite Formation Processes. Battery failure is mainly derived from uncontrollable lithium dendrite formation. This project aims to investigate fundamental lithium dendrite formation mechanism by utilizing a novel in-situ transmission electron microscopy cell. This project expects to build a new set up which is capable of simultaneous in-situ electrical and nanomechanical measurements of lithium dendrite growth. This project aims to reveal how lithium dendrite ....In-depth Investigation of Lithium Dendrite Formation Processes. Battery failure is mainly derived from uncontrollable lithium dendrite formation. This project aims to investigate fundamental lithium dendrite formation mechanism by utilizing a novel in-situ transmission electron microscopy cell. This project expects to build a new set up which is capable of simultaneous in-situ electrical and nanomechanical measurements of lithium dendrite growth. This project aims to reveal how lithium dendrite growth is affected by different surface modifications on the commercial graphite electrodes. The success of the project will lead to a fundamental understanding of the lithium dendrite formation mechanism, enabling the construction of significantly safer batteries.Read moreRead less
Integrated solar to chemical production and membrane concentration system. The efficient conversion of low-cost raw materials to high-value chemicals using solar energy has been a long sought-after goal. This project aims to create an integrated photoreactor and membrane separation system for efficient photocatalytic water splitting. The integrated system will efficiently produce hydrogen and ultrapure hydrogen peroxide, a critical and costly reagent used in the semiconductor and solar panel man ....Integrated solar to chemical production and membrane concentration system. The efficient conversion of low-cost raw materials to high-value chemicals using solar energy has been a long sought-after goal. This project aims to create an integrated photoreactor and membrane separation system for efficient photocatalytic water splitting. The integrated system will efficiently produce hydrogen and ultrapure hydrogen peroxide, a critical and costly reagent used in the semiconductor and solar panel manufacturing industries. The integrated system addresses current challenges in the production of high-quality hydrogen peroxide and demonstrates a practical solar-to-chemical process with economic benefits. It also advances knowledge in the fields of nanomaterials engineering, photocatalytic devices, and membrane technology.Read moreRead less