通过等离子体活化构建用于超级电容器和锌离子电容器的氮掺杂三维分层多孔石墨烯纳米泡沫

Constructing N-doped and 3D Hierarchical Porous graphene nanofoam by plasma activation for supercapacitor and Zn ion capacitor.

作者信息

Wei Song, Wan Caichao, Li Xingong, Su Jiahui, Cheng Wenjie, Chai Huayun, Wu Yiqiang

机构信息

College of Materials Science and Engineering, Central South University of Forestry and Technology, Changsha 410004, PR China.

出版信息

iScience. 2023 Jan 13;26(2):105964. doi: 10.1016/j.isci.2023.105964. eCollection 2023 Feb 17.

DOI:10.1016/j.isci.2023.105964

PMID:36818307

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9932486/

Abstract

Traditional electrode materials still face vital challenges of few active sites, low porosity, complex synthesis process, and low specific capacitance. Herein, N-doped and 3D hierarchical porous graphene nanofoam (N-GNF) is created on carbon fibers (CFs) by employing a facile, fast, and environmentally friendly strategy of N plasma activation. After an appropriated N plasma activation, the graphene nanosheets (GNSs) synthesized by Ar/CH plasma deposition transform into N-GNF successfully. N doping donates rich active sites and increases the hydrophilia, while hierarchical nanoarchitecture exposes an enlarged effective contact area at the interface between electrode and electrolyte and affords sufficient space for accommodating more electrolytes. The as-assembled flexible N-GNF@CFs//Zn NSs@CFs Zn ion capacitor delivered a high energy density of 105.2 Wh kg at 378.6 W kg and initial capacity retention of 87.9% at the current of 2 A g after a long cycle of 10,000.

摘要

传统电极材料仍然面临着活性位点少、孔隙率低、合成过程复杂以及比电容低等重大挑战。在此，通过采用一种简便、快速且环保的氮等离子体活化策略，在碳纤维（CFs）上制备了氮掺杂的三维分级多孔石墨烯纳米泡沫（N-GNF）。经过适当的氮等离子体活化后，通过氩/甲烷等离子体沉积合成的石墨烯纳米片（GNSs）成功转化为N-GNF。氮掺杂提供了丰富的活性位点并增加了亲水性，而分级纳米结构在电极与电解质之间的界面处暴露出更大的有效接触面积，并为容纳更多电解质提供了足够的空间。所组装的柔性N-GNF@CFs//Zn NSs@CFs锌离子电容器在378.6 W kg的功率密度下具有105.2 Wh kg的高能量密度，在2 A g的电流下经过10000次长循环后，初始容量保持率为87.9%。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/369b/9932486/10b07e98cc72/fx1.jpg

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通过等离子体活化构建用于超级电容器和锌离子电容器的氮掺杂三维分层多孔石墨烯纳米泡沫

Constructing N-doped and 3D Hierarchical Porous graphene nanofoam by plasma activation for supercapacitor and Zn ion capacitor.

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