Enhancement of the wettability of graphite-based lithium-ion battery anodes by selective laser surface modification using low energy nanosecond pulses

Enhancement of the wettability of graphite-based lithium-ion battery anodes by selective laser surface modification using low energy nanosecond pulses

The electrolyte filling process of battery cells is one of the time-critical bottlenecks in cell production. Wetting is of particular importance here, since only completely wetted electrode sections are working. In order to accelerate and facilitate this process, the authors of this study developed...

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Bibliographic Details
Published in:International journal of advanced manufacturing technology Vol. 118; no. 5-6; pp. 1987 - 1997
Main Authors: Kleefoot, Max-Jonathan, Enderle, Sebastian, Sandherr, Jens, Bolsinger, Marius, Maischik, Thomas, Simon, Nadine, Martan, Jiří, Ruck, Simon, Knoblauch, Volker, Riegel, Harald
Format: Journal Article
Language:English
Published: London Springer London 2022
Springer Nature B.V
Subjects:
Ablation
Amorphization
Anodes
Application
Binders (materials)
CAE) and Design
Carbon
Carbon black
Computer-Aided Engineering (CAD
Crystal structure
Crystallinity
Drop tests
Electrolytes
Electrolytic cells
Engineering
Graphite
Impact tests
Industrial and Production Engineering
Laser ablation
Lasers
Lithium-ion batteries
Mechanical Engineering
Media Management
Nanosecond pulses
Parameters
Raman spectroscopy
Rechargeable batteries
Surface roughness
Wettability
Wetted electrodes
Wetting
White light interferometry
Short pulsed laser
Lithium-ion battery
Selective laser ablation
Wettability
Anode
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Description
Summary:The electrolyte filling process of battery cells is one of the time-critical bottlenecks in cell production. Wetting is of particular importance here, since only completely wetted electrode sections are working. In order to accelerate and facilitate this process, the authors of this study developed a method to significantly increase the wettability of graphite-based anodes by a laser surface modification using low energy nanosecond laser pulses. The anode surface microstructure was evaluated by means of white-light interferometry and scanning electron microscopy. The assessment of wettability was done by drop test and capillary rise test of the liquid electrolyte. The results show that there is a predominantly selective ablation process for laser energy inputs below 2 J/m by which the graphite active material remains unaffected and the binder material is decomposed. The observed increase in surface roughness correlates with the increasing wettability. Investigations using Raman spectroscopy showed that laser treatment leads to a damage on the crystalline structure of the graphite particle surface. However, treating an entire anode including 6 wt% binder and conductive carbon black has shown that the overall amorphous content of the anodes surface can be reduced by 32% through treating the surface with a laser energy of 1.29 J/m. Up to that point, which is the resulting parameter range for the selective process, it is possible to ablate the amorphous binder and carbon black phase coevally exposing graphite particles while keeping their crystalline structure. Exceeding that range, ablation of the whole anode composite dominates and amorphization of the graphite surface occurs. The electrode’s capacity was tested on half-cells in coin cell format. For the whole laser parameter range investigated, the anodes capacity matches the mass loss caused by laser ablation. No additional capacity loss was observed due to amorphization of the exterior graphite particle’s surface.
ISSN:0268-3768
1433-3015
DOI:10.1007/s00170-021-08004-3