In Situ X‐ray Visualization of the Lithiation Process in a Porous Graphite Electrode in an Operating Li‐Ion Cell

In Situ X‐ray Visualization of the Lithiation Process in a Porous Graphite Electrode in an Operating Li‐Ion Cell

An in situ X‐ray radiography technique to observe an operating Li‐ion cell was developed. Transient behaviors of lithiation processes in a porous graphite electrode were visualized in a specifically designed Li‐ion cell consisting of a lithium‐metal electrode and a graphite electrode, using a transm...

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Veröffentlicht in:ChemElectroChem 2015-10, Vol.2 (10), p.1535-1540
Hauptverfasser: Tsushima, Shohji, Hung, Weihao, Deevanhxay, Phengxay, Kobayashi, Genki, Kanno, Ryoji, Hirai, Shuichiro
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in situ visualization
ion transport
lithiation
lithium-ion batteries
X-ray radiography
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container_end_page 1540
container_issue 10
container_start_page 1535
container_title ChemElectroChem
container_volume 2
creator Tsushima, Shohji
Hung, Weihao
Deevanhxay, Phengxay
Kobayashi, Genki
Kanno, Ryoji
Hirai, Shuichiro
description An in situ X‐ray radiography technique to observe an operating Li‐ion cell was developed. Transient behaviors of lithiation processes in a porous graphite electrode were visualized in a specifically designed Li‐ion cell consisting of a lithium‐metal electrode and a graphite electrode, using a transmission X‐ray microscope with high spatial and temporal resolution. X‐ray attenuation profiles in both 15 and 30 μm thick graphite electrodes under discharge (lithiation) at the 2 C rate were compared. X‐ray attenuation was pronounced near the separator in the thicker graphite electrode during the lithiation process, whereas less variation was observed near the current collector in the electrode. These X‐ray observations indicate less utilization of the thicker graphite electrode, presumably because of the longer Li‐ion transport path and formation of a solid electrolyte interface layer in the porous electrode, resulting in less discharge capacity of the Li‐ion cell. Feed the porous: An in situ visualization technique is developed that uses low‐energy X‐rays with high spatial and temporal resolution, which is applicable to an operating lithium‐ion half‐cell. This technique is operated by a laboratory‐based instrument and used to examine the lithiation behavior in a graphite electrode in a graphite/lithium‐metal cell.
doi_str_mv 10.1002/celc.201500141
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Feed the porous: An in situ visualization technique is developed that uses low‐energy X‐rays with high spatial and temporal resolution, which is applicable to an operating lithium‐ion half‐cell. This technique is operated by a laboratory‐based instrument and used to examine the lithiation behavior in a graphite electrode in a graphite/lithium‐metal cell.</abstract><doi>10.1002/celc.201500141</doi><tpages>6</tpages></addata></record>
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subjects in situ visualization
ion transport
lithiation
lithium-ion batteries
X-ray radiography
title In Situ X‐ray Visualization of the Lithiation Process in a Porous Graphite Electrode in an Operating Li‐Ion Cell
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