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苗小飞等:高性能锂离子电池负极材料一氧化锰/石墨烯复合材料的合成 ·415· 维持在803mAh·g.经不同的电流密度下循环225 [14]Wu ZS,Zhou G M,Yin L C,et al.Graphene/metal oxide com- 圈后,在2.0A·g高电流密度下,比容量依然可以达 posite electrode materials for energy storage.Nano Energy, 到412mAh~g 2012,1(1):107 [15]Srivastava M,Singh J,Kuila T,et al.Recent advances in gra- (3)通过对恒流循环中比容量一电压的微分分析 phene and its metal-oxide hybrid nanostructures for lithium-ion 发现,随着循环次数的增加,在MnO/rGO中观察到了 batteries.Nanoscale,2015,7:4820 新的氧化还原峰,该氧化还原峰在p-MnO中并未出 [16]Geim A K,Novoselov K S.The rise of graphene.Nat Mater, 现.新的氧化还原峰的出现使MnO/rGO实际容量超 2007,6:183 过了一氧化锰的理论容量,石墨烯上残存的含氧基团 [17]Allen M J,Tung V C,Kaner R B.Honeycomb carbon:a review 可能为该氧化还原反应提供了所需的额外氧源. of graphene.Chem Rev,2009,110(1):132 [18]Kucinskis C,Bajars G,Kleperis J.Graphene in lithium ion bat- tery cathode materials:A review.Pouer Sources,2013,240: 参考文献 66 [19]Yang M,Zhong Y R,Zhou X L,et al.Ultrasmall Mno@N- [Evarts E C.Lithium batteries:To the limits of lithium.Nature, rich carbon nanosheets for high-power asymmetric 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anodes for Li-苗小飞等: 高性能锂离子电池负极材料一氧化锰/石墨烯复合材料的合成 维持在 803 mAh·g - 1 . 经不同的电流密度下循环 225 圈后,在 2. 0 A·g - 1高电流密度下,比容量依然可以达 到 412 mAh·g - 1 . ( 3) 通过对恒流循环中比容量--电压的微分分析 发现,随着循环次数的增加,在 MnO / rGO 中观察到了 新的氧化还原峰,该氧化还原峰在 p--MnO 中并未出 现. 新的氧化还原峰的出现使 MnO / rGO 实际容量超 过了一氧化锰的理论容量,石墨烯上残存的含氧基团 可能为该氧化还原反应提供了所需的额外氧源. 参 考 文 献 [1] Evarts E C. Lithium batteries: To the limits of lithium. Nature, 2015,526( 7575) : S93 [2] Reddy M V,Subba Rao G V,Chowdari B V R. Metal oxides and oxysalts as anode materials for Li ion batteries. Chem Rev,2013, 113( 7) : 5364 [3] Li H,Balaya P,Maier J. Li-storage via heterogeneous reaction in selected binary metal fluorides and oxides. J Electrochem Soc, 2004,151( 11) : A1878 [4] Yu X Q,He Y,Sun J P,et al. Nanocrystalline MnO thin film anode for lithium ion batteries with low overpotential. Electrochem Commun,2009,11( 4) : 791 [5] Poizot P,Laruelle S,Grugeon S,et al. Rationalization of the lowpotential reactivity of 3d-metal-based inorganic compounds toward Li. J Electrochem Soc,2002,149( 9) : A1212 [6] Zhong K F,Xia X,Zhang B,et al. MnO powder as anode active materials for lithium ion batteries. 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