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Multifunctional natural agarose as an alternative material for high-performance rechargeable lithium-ion batteries

Agarose, which is one of the natural polysaccharides that is generally extracted from seaweed, has recently attracted great attention as an environmentally-benign building element for a wide variety of applications. Notably, its disaccharide repeating units bearing ether/hydroxyl groups carry unprec...

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Bibliographic Details
Published in:Green chemistry : an international journal and green chemistry resource : GC 2016-01, Vol.18 (9), p.271-2716
Main Authors: Hwang, Gaeun, Kim, Ju-Myung, Hong, Dongki, Kim, Choon-Ki, Choi, Nam-Soon, Lee, Sang-Young, Park, Soojin
Format: Article
Language:English
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Summary:Agarose, which is one of the natural polysaccharides that is generally extracted from seaweed, has recently attracted great attention as an environmentally-benign building element for a wide variety of applications. Notably, its disaccharide repeating units bearing ether/hydroxyl groups carry unprecedented performance benefits far beyond those accessible with traditional synthetic polymers. Herein, intrigued by these unusual chemical features of agarose, we explore its potential applicability as an alternative electrode binder and also as a carbon source for high-performance rechargeable lithium-ion batteries. The agarose binder enables silicon (Si) active materials to be tightly adhered to copper foil current collectors, thereby providing significant improvement in the electrochemical performance of the resulting Si anode (specific capacity = 2000 mA h g −1 and capacity retention after 200 cycles = 71%). In addition, agarose can be exploited as a cathode binder. An LiMn 2 O 4 cathode containing agarose binder shows an excellent cell performance (initial coulombic efficiency of ∼96.2% and capacity retention after 400 cycles of ∼100%). Through the selective carbonization of Si-dispersed agarose, Si/C (hard carbon) composite active materials are successfully synthesized. Eventually, the Si/C composite anode and the LiMn 2 O 4 cathode mentioned above are assembled to produce a full cell featuring the use of agarose as an alternative green material. Benefiting from the exceptional multifunctionality of agarose, the full cell presents a stable cycling performance (capacity retention after 50 cycles of >87%). Multifunctional agarose acts as an effective binder for Si anodes and LiMn 2 O 4 cathodes and also serves as a good carbon source to obtain hard carbon.
ISSN:1463-9262
1463-9270
DOI:10.1039/c5gc02654g