Multifunctional trilayer separator for durable multivalent energy storage. This project aims to develop an important new family of economical, high energy, multivalent batteries based on an abundant element, sulphur. The project plans to design a new battery separator to enable long-term stability in sulphur-based rechargeable batteries. This type of separator is of critical importance in many membrane-involved energy storage technologies. The project plans to use leading-edge durable energy tec ....Multifunctional trilayer separator for durable multivalent energy storage. This project aims to develop an important new family of economical, high energy, multivalent batteries based on an abundant element, sulphur. The project plans to design a new battery separator to enable long-term stability in sulphur-based rechargeable batteries. This type of separator is of critical importance in many membrane-involved energy storage technologies. The project plans to use leading-edge durable energy technologies to strengthen the development of residential energy systems and the involvement of renewable energy sources in modern grid.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101264
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Carbon nanotube-based supercapacitors: breaking the energy density limit. Novel electrodes will be nano-architectured by using ultralong single-walled carbon nanotube arrays and transition metal oxides to produce next-generation supercapacitors. The outcomes will lead to unprecedented energy densities in energy storage devices for sustainable future energy solutions.