A study on the interior microstructures of working Sn particle electrode of Li-ion batteries by in situ X-ray transmission microscopy

@article{Chao2010ASO,
  title={A study on the interior microstructures of working Sn particle electrode of Li-ion batteries by in situ X-ray transmission microscopy},
  author={Sung-Chieh Chao and Yu-Chan Yen and Yen-Fang Song and Yi-ming Chen and Hung-Chun Wu and Nae‐Lih Wu},
  journal={Electrochemistry Communications},
  year={2010},
  volume={12},
  pages={234-237}
}
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In Situ Transmission X-ray Microscopy Study on Working SnO Anode Particle of Li-Ion Batteries
The evolution of the interior microstructures of SnO during electrochemical lithiation/de-lithiation has been visualized by in situ transmission X-ray microscopy (TXM), complemented by in situ X-ray
Study on Microstructural Deformation of Working Sn and SnSb Anode Particles for Li-Ion Batteries by in Situ Transmission X-ray Microscopy
Sn-containing compounds are potential high-capacity anode materials for Li-ion batteries. They, however, suffer from significant dimensional variations during electrochemical lithiation and
Characterization of battery anode materials by X-ray and electron-based imaging techniques
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The internal microstructure of a silicon electrode in a lithium ion battery was visualized by operando synchrotron X-ray radioscopy during battery cycling. The silicon particles were found to change
In situ and Operando Tracking of Microstructure and Volume Evolution of Silicon Electrodes by using Synchrotron X-ray Imaging.
TLDR
The internal microstructure of a silicon electrode in a lithium ion battery was visualized by operando synchrotron X-ray radioscopy during battery cycling and an expansion prolongation phenomenon was discovered whereby some particles continue expanding even after switching the battery current direction and shrinkage would be expected.
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Understanding the microscopic mechanisms of electrochemical reaction and material degradation is crucial for the rational design of high‐performance lithium ion batteries (LIBs). A novel nanobattery
Understanding Stabilization in Nanoporous Intermetallic Alloy Anodes for Li-Ion Batteries Using Operando Transmission X-ray Microscopy.
TLDR
Operando transmission X-ray microscopy showed that during cycling NP-SbSn expands by only 60% in area and then contracts back nearly to its original size with no physical disintegration, which should be useful for designing nanoscale structures in alloying anodes.
Microstructural evolution of tin nanoparticles during in situ sodium insertion and extraction.
TLDR
Excellent cyclability was also observed during the reversible sodiation/desodiation cycles, showing great potential of Sn nanoparticles as a robust electrode material for rechargeable batteries.
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however (for it was the literal soul of the life of the Redeemer, John xv. io), is the peculiar token of fellowship with the Redeemer. That love to God (what is meant here is not God’s love to men)
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