4.7 Article

Biomass-Derived Graphitic Carbon/Co3O4 Nanocomposites with Pseudocapacitance for Lithium Storage

期刊

ACS APPLIED NANO MATERIALS
卷 4, 期 2, 页码 1340-1350

出版社

AMER CHEMICAL SOC
DOI: 10.1021/acsanm.0c02903

关键词

CO3O4; biotemplate; mesopore; pseudocapacitance; lithium-ion battery

资金

  1. International Science & Technology Cooperation Program of China [2016YFE0115100]
  2. Scientific and Technological Innovation Talents of Harbin [2016RAQXJ005]
  3. Project of Natural Science Foundation of Heilongjiang Province [B2015007]
  4. Young Innovation Talents of college in Heilongjiang Province [UNPYSCT-2016074, UNPYSCT2017121]
  5. Key Laboratory of Functional Inorganic Material Chemistry, Ministry of Education, Heilongjiang University

向作者/读者索取更多资源

The reuse of waste biomass resources for sustainable development is a popular theme, and the synthesis of CO3O4/C-2 nanocomposites from waste scallion root has shown excellent performance in lithium storage, with high capacity and long-cycling stability attributed to its unique nanostructure.
The reuse of waste biomass resources has recently become one of the most popular themes in the sustainable development of human society. To this end, waste scallion root was used as a biotemplate and carbon source to synthesize graphitic carbon-doped mesoporous CO3O4 nanocomposites (CO3O4/C) through a simple cobalt salt impregnation, carbonization, and low-temperature oxidation method. The effect of different carbon contents on the nanostructure and electrochemical performance is investigated. The hierarchical microtubes with a ribs-shaped inner wall in the product oxidized at 320 degrees C (CO3O4/C-2) are formed by the cross-linking of uniform small CO3O4 nanoparticles and 39.9% biomass-derived carbon. The CO3O4/C-2 nanocomposite has a large specific surface area of 360.2 m(2).g(-1), uniform mesopore size of 2.35 nm, and abundant oxygen vacancy defects. Such a unique nanostructure can exhibit a good pseudocapacitance behavior during the charge/discharge process, thereby effectively enhancing the lithium storage performance. The CO3O4/C-2 nanocomposite exhibits a high capacity and good rate capability. Even at 1.0 A.g(-1), it can still retain a capacity of 620 mA h g(-1) after 1500 cycles. The superior capacity retention and long-cycling stability can be assigned to the synergistic effect of the unique nanostructure of the CO3O4/C-2 material (a uniform mesopore and large specific surface area), appropriate graphitic carbon doping, and pseudocapacitance contribution. Therefore, the reuse strategy of the waste scallion root biomass resource conforms to the concept of sustainable development and also provides a useful reference for the synthesis of other nanostructured anode materials with excellent performance.

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