Practical Challenges Associated with Catalyst Development for the Commercialization of Li-air Batteries

Abstract: Li-air cell is an exotic type of energy storage and conversion device considered to be half battery and half fuel cell. Its successful commercialization highly depends on the timely development of key components. Among these key components, the catalyst (i.e., the core portion of the air electrode) is of critical importance and of the upmost priority. Indeed, it is expected that these catalysts will have a direct and dramatic impact on the Li-air cell's performance by reducing overpotentials, as well as by enh… Show more

“…Its successful commercialization will depend on the timely development of key components (including nanocatalysts, which will be a key part of the air electrode). 593 Within the next 30 years or longer, cathodes cocatalyst components for Li-air batteries may also be required to be nanosized, and CHFS will be an ideal way to make such materials. Looking to the future, there are exciting possibilities to develop multivalent cathodes (e.g., Al or Mg−ion batteries) such as those based around spinel structures 594 possessing large pores.…”

Continuous Hydrothermal Synthesis of Inorganic Nanoparticles: Applications and Future Directions

“…Its successful commercialization will depend on the timely development of key components (including nanocatalysts, which will be a key part of the air electrode). 593 Within the next 30 years or longer, cathodes cocatalyst components for Li-air batteries may also be required to be nanosized, and CHFS will be an ideal way to make such materials. Looking to the future, there are exciting possibilities to develop multivalent cathodes (e.g., Al or Mg−ion batteries) such as those based around spinel structures 594 possessing large pores.…”

Continuous Hydrothermal Synthesis of Inorganic Nanoparticles: Applications and Future Directions

A study of novel hydrophobic P(TFE) particles dispersed electrospun gel polymer electrolyte fibrous membranes

Review on mechanisms and continuum models of multi-phase transport phenomena in porous structures of non-aqueous Li-Air batteries