Fe-N-C decorated fibrous network-wrapped biomass SiOx/C with gradient conductive structure for high performance Li-ion battery anodes

[Display omitted] •Catalytic effect of Fe-N-C contribute to enhanced electrochemical reversibility.•Indirect interface contact of SiO2 and biomass carbon prevents the formation of SiC.•“Double carbon” structured promotes the formation of stable LiF-rich SEI.•The decomposition of iron salts provides...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2023-12, Vol.477, p.147178, Article 147178
Main Authors: Kong, Xiangzhong, Xi, Ziyang, Jiang, Yingjie, Li, Shi, Chen, Xi, Zhang, Jing, Wang, Lihua, Wan, Zhongmin, Pan, Anqiang
Format: Article
Language:English
Subjects:
Fe-N-C
Gradient conductive structure
Lithium-ion batteries
Rice husk
SiOx/C
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Summary:[Display omitted] •Catalytic effect of Fe-N-C contribute to enhanced electrochemical reversibility.•Indirect interface contact of SiO2 and biomass carbon prevents the formation of SiC.•“Double carbon” structured promotes the formation of stable LiF-rich SEI.•The decomposition of iron salts provides abundant defects for Li+ transport.•The LiFePO4‖Fe-N-C/SiOx/C-3 full cell delivers good electrochemical performance. Fabrication of high performance silicon-based materials derived from natural biowastes plays a significant role in the green recycling of biomass resources. However, low utilization of organic component and poor lifespan hinders the its large scale applications. Herein, biomass derived SiOx/C-3 composite was encapsulated into Fe-N-C decorated carbon nanofibers network (Fe-N-C/SiOx/C-3) by a facile magnesiothermic reduction combined with electrostatic spinning strategy. The ingenious designed indirect contact biomass carbon/SiO2 interface effectively utilizes the organic components of rice husk and prevents the formation of SiC during reduction process. HAADF-STEM and XPS characterization confirmed the presence of Fe single atoms and the formation of Fe-N coordination bonds. Benefiting from the unique carbonaceous network and catalytic effect of Fe-N-C, the Fe-N-C/SiOx/C-3 exhibit excellent lithium storage properties (832.6 mAh g−1 after 250 cycles at 0.1 A g−1). Even at high current density (1 A g−1), the electrode can still remain a capacity of 602 mAh g−1 after 1000 cycles with capacity retention of 79.4%. The ex-situ SEM and XPS characterizations demonstrated that the gradient structure consisting of inner biomass-derived carbon and flexible carbonaceous networks enhanced the overall conductivity and structural integrity of the composite. Furthermore, the catalytic effect of Fe-N-C facilitates the rapidly formation of stable LiF-rich solid electrolyte interphase (SEI) films during charge/discharge process. The assembled LiFePO4‖Fe-N-C/SiOx/C-3 full cell shows excellent electrochemical performance (106.5 mAh g−1 after 100 cycles at 0.1A g−1), which provides insights into the fabrication of high performance biomass derived silicon based anodes.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2023.147178