Tingting Li, Shaokang Yang, Yunpeng Zuo, Wei Li, Hongwei Yue, Štěpán Kment and Yang Chai
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引用次数: 0
Abstract
To improve the intrinsic property of Ni(OH)2 for advanced supercapacitors, structural and valence engineering are combined here to prepare porous β-Ni(OH)x–SO4 (NSO) interlaminar materials. NSO has an expanded interplanar spacing and in-plane porous channels, thus offering a 3D accessible structure for the charging and discharging process. The intercalation of SO42? can retain the layer spacing of NSO through hydrogen bond during the charge transport and effectively drive electrons close to the Fermi level of NSO, which significantly enhances the stability and conductivity of the sample. The rigid interlayer space and in-plane channels enable NSO to exhibit a high specific capacity of 212.5 mA h g?1 at 3 A g?1. The assembled asymmetric supercapacitor device shows a high energy density of 41.2 W h kg?1 at 796.9 W kg?1 and maintains 86.8% capacity retention after 10?000 cycles at 4 A g?1.
为了改善用于先进超级电容器的Ni(OH)2的本征性能,本文将结构工程和价态工程相结合,制备了多孔β-Ni(OH) x-SO4 (NSO)层间材料。NSO具有扩展的面间间距和面内多孔通道,从而为充放电过程提供3D可访问结构。SO42的插入?可以在电荷输运过程中通过氢键保持NSO的层间距,并有效地驱动电子接近NSO的费米能级,显著提高了样品的稳定性和导电性。刚性的层间空间和面内通道使NSO具有212.5 mA h g的高比容量。在3g时。组装的非对称超级电容器器件显示出41.2 W h kg?796.9瓦特公斤?10?后容量保留率为86.8%。4 g?1, 000次循环。
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