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Suppression of dendrites and granules in surface-patterned Li metal anodes using CsPF6

Title
Suppression of dendrites and granules in surface-patterned Li metal anodes using CsPF6
Authors
Kim, SeokwooChoi, JunyoungLee, HongkyungJeong, Yong-CheolLee, Yong MinRyou, Myung-Hyun
DGIST Authors
Lee, HongkyungLee, Yong Min
Issue Date
2019-02
Citation
Journal of Power Sources, 413, 344-350
Type
Article
Article Type
Article
Author Keywords
Cesium hexafluorophosphateCsPF6 additiveLithium dendriteLithium metal anodesLithium secondary batteries
Keywords
FREE LITHIUM DEPOSITIONPERFORMANCEMECHANISMSINTERLAYERGRAPHENE
ISSN
0378-7753
Abstract
Unexpected Li deposition during plating, which causes low Coulombic efficiency and safety issues, limits the use of Li metal as an anode in commercial secondary batteries. With the recently developed micro-patterned Li metal anodes, dendrite formation during high current Li plating (2.4 mA cm−2) has successfully been reduced, as Li ions are guided into the patterned holes. However, the uncontrolled formation of granular Li is still observed in this material. To overcome these shortcomings, we have introduced cesium hexafluorophosphate into micro-patterned Li metal anodes. This additive employs the self-healing electrostatic shield mechanism to effectively reduce the formation of granular Li and Li dendrites, thereby significantly improving the electrochemical performance of the anodes even when only small amounts (0.05 M) of electrolyte are used. Our experiments revealed that batteries employing surface-patterned Li metal anodes with cesium hexafluorophosphate maintained 88.7% (96.6 mAh g−1) of their initial discharge capacity after the 900th cycle (Charging current density: C/2, 0.6 mA cm−2, Discharging current density: 1C, 1.2 mA cm−2), which is three times higher than the capacity observed with surface-patterned Li metal anodes without the additive (discharge capacity starts to decrease from 300 cycles). © 2018
URI
http://hdl.handle.net/20.500.11750/9575
DOI
10.1016/j.jpowsour.2018.12.052
Publisher
Elsevier BV
Related Researcher
  • Author Lee, Hongkyung Electrochemical Materials & Devices Laboratory
  • Research Interests Batteries; Electrochemistry; Interfaces
Files:
There are no files associated with this item.
Collection:
Department of Energy Science and EngineeringElectrochemical Materials & Devices Laboratory1. Journal Articles
Department of Energy Science and EngineeringBattery Materials & Systems LAB1. Journal Articles


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