Title
Fracture of nanostructured Sn/C anodes during Li-insertion
Document Type
Article
Publication Date
11-25-2011
Abstract
Printers; Three dimensional displays; Open source hardware; Fabrication; Scientific instruments; Manufacturing processes Sn/C nanocomposites, in the form of Sn or SnO2 islands attached on carbon surfaces, provide a high initial capacity when used as anodes in rechargeable Li-ion batteries. Upon Li-insertion, however, the Sn undergoes significant volume changes which result in fracture and, hence, a fade in capacity. In the present study a detailed electron microscopy analysis was used for the first time to document the fracture that occurred throughout the Li-insertion and de-insertion process. Particularly, scanning and transmission (SEM&TEM) electron microscopy was performed on four different Sn/C nanocomposites, before and after, electrochemical cycling. Analysis of the Sn particle size distribution showed that the greatest amount of fracture occurred during the first cycle. It was concluded that both the particle volume average and the area fraction of the as prepared Sn or SnO2 islands must be kept at low values in order to minimize fracture and, therefore, retain a stable capacity. A simple empirical expression was, hence, presented to relate the capacity with the initial microstructure.
Publication Title
Materials Science and Engineering: A
Recommended Citation
Aifantis, K. E.,
Hancock, M.,
Sanders, P. G.,
&
Hackney, S. A.
(2011).
Fracture of nanostructured Sn/C anodes during Li-insertion.
Materials Science and Engineering: A,
529, 55-61.
http://doi.org/10.1016/j.msea.2011.08.060
Retrieved from: https://digitalcommons.mtu.edu/materials_fp/121
Publisher's Statement
© 2011 Elsevier B.V. Publisher’s version of record: http://dx.doi.org/10.1016/j.msea.2011.08.060