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Energy Focus: Lithium-ion intercalation visualized in situ with new atomic-scale imaging technique

Published online by Cambridge University Press:  04 May 2016

Abstract

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Other
Copyright
Copyright © Materials Research Society 2016 

Intercalation in rechargeable lithium-ion batteries—the process where lithium ions pack themselves in between adjacent two-dimensional layers of an electrode material—is integral to the operation of the batteries. The complete dynamics of this process have not yet been visualized. M. Azhagurajan from Tohoku University, Y.-G. Kim from the California Institute of Technology, and their colleagues have now succeeded in this goal, as reported in their article published recently in the Journal of the American Chemical Society (doi:10.1021/jacs.5b11849).

The major technological advance achieved by the team was the development of a combined laser confocal microscopy-differential interference microscopy (LCM-DIM) imaging technique, which enabled single atomic step heights down to tenths of nanometers to be resolved. Using this technique, the researchers examined the intercalation and deintercalation of lithium within MoS2 layers, recording and analyzing contrasts in the images. They found that intercalation occurs layer by layer in a stepwise manner; beginning at the layer’s edge, a lithium ion enters between MoS2 layers. The ion then accommodates a second ion by shifting one unit cell toward the interior of the layer. These two intercalated ions then shift one unit cell toward the interior to accommodate a third ion. This process continues until a layer of MoS2 is almost completely intercalated with Li ions before intercalation in the subsequent layer begins. Deintercalation proceeds in a similar way.

The layer-by-layer process of intercalation and deintercalation gives rise to a distinct phase separation between the intercalated and non-intercalated regions. Using the LCM-DIM in situ dynamic visualization technique, the team was able to see the intercalated region expand as a front moving through the material, much like a layer of water expands to cover a smooth surface. With application of greater current, net-like disruptions occurred in the layer surface. These reticular regions later developed into cracks in the MoS2 surface.

(a) Laser confocal microscope combined with a differential interference contrast microscope image of Li-ion intercalation of the first intercalated layer of MoS2, where the time marked in the image shows the start of the appearance of the new domain. The image was obtained at 1.25 V versus Li, and taken in an area of 70 × 70 µm2. (b,c) Schematic of Li-ion intercalation within MoS2 layers along the b-axis. The first layer underneath the selvedge is intercalated first to (near) completion prior to the intercalation of the second layer. A solvated Li ion is initially intercalated at the steps. (d) A row of four intercalated Li ions takes in an incoming Li ion, making the row with five ions. Credit: Journal of the American Chemical Society.

The LCM-DIM opens the door to detailed analysis of atomic-scale surface phenomena that are accompanied by changes in optical properties, potentially ushering in novel discoveries and advances in battery technology.