With the launch of wearable devices and smartphones that require a high capacity of electricity such as foldable phones and 5G phones, the interest in batteries is increasing and various battery types have been developed. For example, flexible batteries embedded in a mobile watch band or wireless power sharing batteries that have developed from wireless charging. However, there is no manufacture of a battery that produces a thousand milliamp Hour (mAh) capacity that is foldable. Recently, a research team from Korea developed a monolithic electrode that can replace heavy copper collectors and enabled development of a flexible battery with high capacity. For more information see the IDTechEx report on Flexible, Printed and Thin Film Batteries 2019-2029.
Professor Soojin Park of Chemistry and Division of Advanced Materials Science with his postdoctoral researcher, Jaegeon Ryu and his PhD student, Jieun Kang successfully developed a flexible battery with a thin and three-dimensional organic electrode in collaboration with the Korea Institute of Materials Science.
Furthermore, they were able to lower the weight of a battery by 10 times more than the conventional copper collector by using a three-dimensional copper collector. Instead of using a graphite anode, they utilized organic materials and were able to increase the energy density of a battery by four times and more. Their research establishment was published in the recent issue of ACS Nano.
Electrical conductivity of an organic material is low and there was no solution to integrate collector and organic material. For this reason, it had not been possible to demonstrate a monolithic electrode with organic materials before their study. The research team studied a new way to replace a current collector that makes a battery heavy and a graphite anode with low energy density in order to lower the weight of battery innovatively.
The team produced a three-dimensional structure with high electrical conductivity by using single-walled carbon nanotube (SWCNT) aerogels. Here, they constructed thin monolithic organic electrodes by coating a nanometer-scale imide-based network (IBN)2) organic material.
The three-dimensional monolithic electrodes coated with 8nm thin and adjustable thick organic IBN layers delivered capacity of up to 1550 mA h g-1 and were possible to recharge more than 800 times. These electrodes were coated with organic materials. Despite their poor intrinsic electrical conductivity, they had high electrical conductivity and they also demonstrated the improved electrochemical performances of a rechargeable battery by helping fast transfer of lithium through abundant redox-active sites. Moreover, thickness of coated organic materials can be controlled easily and they were able to improve the current density of organic electrodes greatly.
The newly developed electrode can replace the metal-based collector and this enables development of light and flexible rechargeable batteries which later can be applied to wearable electronic devices, flexible devices, telecommunication and next generation electric vehicles.
Professor Soojin Park who led the research commented, "We can lower the weight of a rechargeable battery enormously by using this newly developed monolithic electrode with SWCNT organic materials. This can overcome the limitations of the conventional rechargeable battery and can realize flexibility and weight lightening of an organic battery."
Top image: Royole
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