Activation-free N-doped porous carbon to enhance surface-driven K storage vs intercalation dominated Na storage

[Display omitted] Carbonaceous materials show more and more obvious applications in potassium (K) ion battery (KIB) and sodium (Na) ion battery (NaIB) because K and Na have higher reserves than lithium (Li). However, the rate performance and cycle stability of KIBs and NaIBs are still hindered by hu...

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Bibliographic Details
Published in:Applied surface science 2020-03, Vol.506, p.144909, Article 144909
Main Authors: Chen, Zhi, Liao, Jiaxuan, Li, Wenlei, Song, Yaochen, Chen, Cheng, Yang, Jian, Xu, Ziqiang, Feng, Tingting, Wu, Mengqiang
Format: Article
Language:English
Subjects:
Activation-free
Nitrogen-doped
Porous carbon
Potassium ion battery (KIB)
Sodium ion battery (NaIB)
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Summary:[Display omitted] Carbonaceous materials show more and more obvious applications in potassium (K) ion battery (KIB) and sodium (Na) ion battery (NaIB) because K and Na have higher reserves than lithium (Li). However, the rate performance and cycle stability of KIBs and NaIBs are still hindered by huge volume change during ions insertion-extraction process and poor kinetics caused by larger volume of K+ and Na+ ions. Compared to graphite and hard carbon, nitrogen (N)-doped porous carbonaceous materials may provide good interfacial wettability and numerous ion transport channels, but low first coulombic efficiency is detrimental to the application of full-battery. Here, N-doped porous carbon (NPC) with a providential specific surface area is synthesized by a facile and activation-free way. Benefiting from N-doping and porous structure, KIBs and NaIBs display an enhanced rate capacity and cycle performance. The storage mechanism and kinetic characteristics of K and Na ion during charge and discharge are also discussed. Comprehensive performance indicates that NPC can obtain a better improvement in surface-driven KIBs than intercalation dominated NaIBs, and can provide some new design concepts for practical applications.
ISSN:0169-4332
DOI:10.1016/j.apsusc.2019.144909