Doping-template approach of porous-walled graphitic nanocages for superior performance anodes of lithium ion batteries

Sheng, Zhao Min; Chang, Xin; Chen, Yu Hang; Cheng, Hong; Li, Na Na; Chang, Chengkang; Jia, Run Ping; Han, Sheng

doi:10.1039/c7ra07859e

Cited by 15 publications

(2 citation statements)

References 33 publications

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“…As the comparison, interfacial lithium-ion transfer reaction at the interface between GCNS electrode and organic electrolyte solutions were investigated beforehand. In addition, the effect of the structural difference of CNSs prepared at different temperature for interfacial lithium/sodium-ion transfer reaction was also investigated because the defects in the graphitic materials [21,22] and the gaps between graphene layers inside graphitic materials [23,24] influence the diffusion of lithium/sodium-ion. Our group previously reported that the sodium-ion insertion and diffusion inside CNSs seemed to be promoted using CNSs treated at low temperature due to the defects and large interlayer distances [8].…”

Section: Introductionmentioning

confidence: 99%

Kinetic properties of sodium-ion transfer at the interface between graphitic materials and organic electrolyte solutions

et al. 2021

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Graphitic materials cannot be applied for the negative electrode of sodium-ion battery because the reversible capacities of graphite are anomalously small. To promote electrochemical sodium-ion intercalation into graphitic materials, the interfacial sodium-ion transfer reaction at the interface between graphitized carbon nanosphere (GCNS) electrode and organic electrolyte solutions was investigated. The interfacial lithium-ion transfer reaction was also evaluated for the comparison to the sodium-ion transfer. From the cyclic voltammograms, both lithium-ion and sodium-ion can reversibly intercalate into/from GCNS in all of the electrolytes used here. In the Nyquist plots, the semi-circles at the high frequency region derived from the Solid Electrolyte Interphase (SEI) resistance and the semi-circles at the middle frequency region owing to the charge-transfer resistance appeared. The activation energies of both lithium-ion and sodium-ion transfer resistances were measured. The values of activation energies of the interfacial lithium-ion transfer suggested that the interfacial lithium-ion transfer was influenced by the interaction between lithium-ion and solvents, anions or SEI. The activation energies of the interfacial sodium-ion transfer were larger than the expected values of interfacial sodium-ion transfer based on the week Lewis acidity of sodium-ion. In addition, the activation energies of interfacial sodium-ion transfer in dilute FEC-based electrolytes were smaller than those in concentrated electrolytes. The activation energies of the interfacial lithium/sodium-ion transfer of CNS-1100 in FEC-based electrolyte solutions were almost the same as those of CNS-2900, indicating that the mechanism of interfacial charge-transfer reaction seemed to be the same for highly graphitized materials and low-graphitized materials each other. Graphic abstract

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Section: Introductionmentioning

confidence: 99%

Kinetic properties of sodium-ion transfer at the interface between graphitic materials and organic electrolyte solutions

et al. 2021

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“…15,16 In recent years, many studies have investigated methods to overcome the above defects: one strategy is loading these active materials on a conductive framework (such as graphene, porous carbon, amorphous carbon) to enhance the transfer of electrodes; [17][18][19][20][21] the preparation of an active materials@shell structure is another strategy to buffer the excessive volume effect as the strong skeleton of shells limits the volume change of active materials in charge/ discharge processes. 8,[22][23][24][25][26][27] Additionally, modifying the structure of electrodes is also an efficient strategy to conquer the above challenges. [28][29][30][31][32] Fe 3 O 4 /Cu nanorod anodes were fabricated by a two-step approach: Cu nanorods were grown using a electrochemically assisted template method and then Fe 3 O 4 nanoparticles were electrodeposited.…”

Section: Introductionmentioning

confidence: 99%

Layer-by-layer anodes with an orientation-arranged structure induced by magnetic field for high-performance lithium ion batteries

Sheng

Huang

et al. 2023

Sustainable Energy Fuels

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Evaluation and screening of Si-based anode materials in commercial Li-ion cells for electric vehicle applications

Singh

Kepler²,

Kumar³

et al. 2022

J Appl Electrochem

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Doping-template approach of porous-walled graphitic nanocages for superior performance anodes of lithium ion batteries

Abstract: Removal of the N-doped template creates nanopores in the shells of nanocages. The created nanopores enhance fast ion diffusion.

Cited by 15 publications

References 33 publications

Kinetic properties of sodium-ion transfer at the interface between graphitic materials and organic electrolyte solutions

Kinetic properties of sodium-ion transfer at the interface between graphitic materials and organic electrolyte solutions

Layer-by-layer anodes with an orientation-arranged structure induced by magnetic field for high-performance lithium ion batteries

Evaluation and screening of Si-based anode materials in commercial Li-ion cells for electric vehicle applications

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