In-situ synthesis of graphene nanosheets encapsulated silicon nanospheres by thermal plasma for ultra-stable lithium storage
2022
Yang, Zongxian | Liu, Chang | Liu, Xiang | Du, Yu | Jin, Huacheng | Ding, Fei | Li, Baoqiang | Ouyang, Yuge | Bai, Liuyang | Yuan, Fangli
Owing to its high capacity, silicon (Si) is a promising anode for meeting the escalating need for batteries with high energy density. Nonetheless, the substantial volumetric variation generated by lithiation/delithiation often results in the pulverization of Si, which substantially lowers its cycle stability. Graphene/graphene nanosheets (GNSs) with higher electrical conductivity and mechanical strength are anticipated to overcome these obstacles when employed as the coating matrix of silicon. Unfortunately, the majority of Si@graphene composites are not manufactured in situ, so that graphene is hardly to entirely encapsulate Si.The low-quality coating leads to the exposure of Si after cycles, resulting in a short cycle life. Herein, graphene nanosheets encapsulated silicon nanospheres (Si@GNSs) are synthesized in situ using a radio-frequency (RF) thermal plasma system, in which graphene and Si have strong interfacial chemical interactions. Further, free-standing Si@GNSs/reduced graphene oxide (Si@GNSs/rGO) paper was prepared using graphene oxide (GO) as a special ‘binder’. When Si@GNSs/rGO paper is directly used as anode electrodes, it demonstrates a high reversible capacity (2270 mAh g⁻¹ at 0.2 A g⁻¹), outstanding rate performance (1569 mAh g⁻¹ at 5.0 A g⁻¹) and ultra-stable cycle performance (capacity retention of 98.55% for 2000 cycles at 3.0 A g⁻¹).
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