New Insight into the Solid Electrolyte Interphase with Use of a Focused Ion Beam

Zhang, Hongli; Li, Feng; Liu, Chang; Tan, Jun; Cheng, Hui‐Ming

doi:10.1021/jp053311a

Cited by 90 publications

(67 citation statements)

References 37 publications

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“…It is well known that the loss of continuity and conductivity within battery electrodes caused by micro-scale fracture is one of the major causes for the degradation in Li-ion batteries [1][2][3]. Specific effects include the loss of electrical contact, isolation of active materials from the conductive matrix, and increased cell internal resistance [4].…”

Section: Introductionmentioning

confidence: 99%

On the fragmentation of active material secondary particles in lithium ion battery cathodes induced by charge cycling

Sun

Sui

Song

et al. 2016

Extreme Mechanics Letters

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Section: Introductionmentioning

confidence: 99%

On the fragmentation of active material secondary particles in lithium ion battery cathodes induced by charge cycling

Sun

Sui

Song

et al. 2016

Extreme Mechanics Letters

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“…Investigations revealed that during cycling tests, electrolytes penetrated spherical graphite, causing surface cracks (Zhang et al, 2005). The capacity of spherical graphite, however, faded while process.…”

Section: Resultsmentioning

confidence: 99%

The improvement on capacity retention of silicon/graphite composites with TiN additive as anode materials for Li-ion battery

Lee

Tsai

2008

Journal of Materials Processing Technology

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“…This damage feature is consistent with those reported in the literature for carbon electrodes. [11,12,[51][52][53] It is likely that most damage to the uncoated CFs occurred prior to the establishment of the solid electrolyte layer. [7,8] …”

Section: Microstructural and Compositional Characterization Of Sn-mentioning

confidence: 99%

Microstructural Characterization of Nanocrystalline Sn-Coated Carbon Fibre Electrodes Cycled in Li-Ion Cells

Bhattacharya

Shafiei

Alpas

2015

Metallurgical and Materials Transactions E

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The mechanisms of electrochemical capacity retention and eventual degradation in composite anodes prepared by electrodepositing nanocrystalline Sn coating on carbon fibres (CF), Sn-CF, were studied using in situ optical microscopy, high-resolution scanning and transmission electron microscopy. Specific capacity changes of Sn-CF anodes (vs Li/Li + ) were observed to take place in three stages: during the first two galvanostatic cycles, a rapid capacity decrease (from 1045 to 930 mAh g À1 ) occurred, which was followed by a steady-state stage where the capacity remained constant at 922 ± 22 mAh g À1 . The fast capacity drop of Sn-CF in the first cycle was attributed to the partial decohesion of Sn from CFs although the carbon substrate remained unaffected due to formation of a layer from the solid electrolyte reduction products. The pure Sn electrode with a higher initial specific capacity than the Sn-CF displayed a rapid decrease in the same range, whereas the specific capacity of the uncoated CF was already much lower as the fibres were severely damaged in the first cycle.

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New Insight into the Solid Electrolyte Interphase with Use of a Focused Ion Beam

Cited by 90 publications

References 37 publications

On the fragmentation of active material secondary particles in lithium ion battery cathodes induced by charge cycling

On the fragmentation of active material secondary particles in lithium ion battery cathodes induced by charge cycling

The improvement on capacity retention of silicon/graphite composites with TiN additive as anode materials for Li-ion battery

Microstructural Characterization of Nanocrystalline Sn-Coated Carbon Fibre Electrodes Cycled in Li-Ion Cells

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