Lee Jae Seob, Jo Min Su, Saroha Rakesh, Jung Dae Soo, Seon Young Hoe, Lee Jun Su, Kang Yun Chan, Kang Dong-Won, Cho Jung Sang
Department of Engineering Chemistry, Chungbuk National University, 1, Chungdae-Ro, Seowon-Gu, Cheongju-si, Chungbuk, 361-763, Republic of Korea.
Energy & Environmental Division, Korea Institute of Ceramic Engineering & Technology (KICET), 101 Soho-Ro, Jinju-si, Gyeongsangnam-do, 52581, Republic of Korea.
Small. 2020 Aug;16(32):e2002213. doi: 10.1002/smll.202002213. Epub 2020 Jul 2.
Hierarchically well-developed porous graphene nanofibers comprising N-doped graphitic C (NGC)-coated cobalt oxide hollow nanospheres are introduced as anodes for high-rate Li-ion batteries. For this, three strategies, comprising the Kirkendall effect, metal-organic frameworks, and compositing with highly conductive C, are applied to the 1D architecture. In particular, NGC layers are coated on cobalt oxide hollow nanospheres as a primary transport path of electrons followed by graphene-nanonetwork-constituting nanofibers as a continuous and secondary electron transport path. Superior cycling performance is achieved, as the unique nanostructure delivers a discharge capacity of 823 mAh g after 500 cycles at 3.0 A g with a low decay rate of 0.092% per cycle. The rate capability is also noteworthy as the structure exhibits high discharge capacities of 1035, 929, 847, 787, 747, 703, 672, 650, 625, 610, 570, 537, 475, 422, 294, and 222 mAh g at current densities of 0.5, 1.5, 3, 5, 7, 10, 12, 15, 18, 20, 25, 30, 40, 50, 80, and 100 A g , respectively. In view of the highly efficient Li ion/electron diffusion and high structural stability, the present nanostructuring strategy has a huge potential in opening new frontiers for high-rate and long-lived stable energy storage systems.
具有N掺杂石墨化碳(NGC)包覆的氧化钴空心纳米球的分级良好的多孔石墨烯纳米纤维被引入作为高倍率锂离子电池的阳极。为此,将包括柯肯达尔效应、金属有机框架以及与高导电性碳复合的三种策略应用于一维结构。特别地,NGC层作为电子的主要传输路径包覆在氧化钴空心纳米球上,随后是构成石墨烯纳米网络的纳米纤维作为连续的二级电子传输路径。实现了优异的循环性能,因为这种独特的纳米结构在3.0 A g下500次循环后放电容量为823 mAh g,每循环的低衰减率为0.092%。倍率性能也值得注意,因为该结构在0.5、1.5、3、5、7、10、12、15、18、20、25、30、40、50、80和100 A g的电流密度下分别表现出1035、929、847、787、747、703、672、650、625、610、570、537、475、422、294和222 mAh g的高放电容量。鉴于高效的锂离子/电子扩散和高结构稳定性,目前的纳米结构化策略在为高倍率和长寿命稳定储能系统开辟新领域方面具有巨大潜力。
