An international research team at the International Center for Materials 
Nanoarchitectonics (WPI-MANA) has worked to improve the ionic conductivity of 
anion-exchange membranes (AEMs) made from layered double hydroxides (LDHs), 
laying the foundation for their use in many electrochemical applications.

(Image: 
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LDHs are inorganic compounds that can be made into extremely thin "nanosheets." 
These flexible sheets are well-suited to serve as AEMs, which have a wide range 
of applications, including the manufacture of batteries, water treatment, and 
electrolysis. 

LDHs have ultrahigh ionic conductivity towards hydroxide ions, which 
facilitates the flow of current. Although LDH nanosheets can reach high levels 
of ionic conductivity of 10 to the power of minus 1 S/cm, this value only 
affects ions moving in the in-plane direction; that is, along the nanosheet. In 
contrast, their ionic conductivity through the nanosheet --in the cross-plane 
direction-- is about 10 to the power of minus 6 S/cm, which is five orders of 
magnitude lower. This hinders fast ionic conduction across AEMs comprising 
restacked LDH nanosheets.

Fortunately, a research team from WPI-MANA, led by Prof. Renzhi Ma, has now 
found a solution to this problem. They used a simple vacuum-assisted filtration 
process to combine LDH nanosheets with LDH nanoparticles, producing a hybrid 
composite membrane. This membrane exhibited high ionic conductivity in both the 
in-plane and cross-plane directions.

The researchers proposed that introducing nanoparticles reduced the restacking 
order of the nanosheets. This created diverse ion-conducting pathways in the 
composite membrane, ultimately boosting its ionic conductivity. "By changing 
the orientation of the nanosheets, their ultrahigh conductivity along the 
in-plane was leveraged to achieve fast transmembrane ionic transport," explains 
Prof. Ma. The composite membrane achieved a conductivity level of 10 to the 
power of minus 2 S/cm (about 10,000 times higher than pure LDH nanosheets) in 
the cross-plane direction.

Prof. Ma says, "The excellent conductivity of our composite membranes will 
unlock their potential use as competitive AEMs for platinum-free 
electrochemical energy storage and conversion." The team's efforts will 
accelerate the development of less expensive AEMs for next-generation energy 
and environmental technologies. 

Research Highlights Vol. 81
https://www.nims.go.jp/mana/research/highlights/vol81.html

MANA Research Highlights
https://www.nims.go.jp/mana/research/highlights/


Source: International Center for Materials Nanoarchitectonics (WPI-MANA), 
National Institute for Materials Science (NIMS)