Gamma(ɣ)-MnO2/rGO Fibered Cathode Fabrication from Wet Spinning and Dip Coating Techniques for Cable-Shaped Zn-Ion Batteries

Cable/fiber-shaped Zn-ion batteries are designed to power wearable electronics that require high flexibility to operate on human body. However, one of technical challenges of these devices is the complexity and high cost for manufacturing fibered cathode. In this work, we demonstrated gamma manganes...

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Bibliographic Details
Published in:Advanced fiber materials (Online) 2022-06, Vol.4 (3), p.457-474
Main Authors: Subjalearndee, Nakarin, He, Nanfei, Cheng, Hui, Tesatchabut, Panpanat, Eiamlamai, Priew, Limthongkul, Pimpa, Intasanta, Varol, Gao, Wei, Zhang, Xiangwu
Format: Article
Language:English
Subjects:
Carbon black
Cathodes
Chemical reduction
Chemical vapor deposition
Chemistry and Materials Science
Crystal structure
Electrochemical analysis
Electrolytes
Electrons
Energy storage
Flexibility
Fluorides
Graphene
Graphite
Homogeneity
Immersion coating
Intercalation
Manganese dioxide
Manufacturing
Materials Engineering
Materials Science
Multi wall carbon nanotubes
Nanoscale Science and Technology
Performance evaluation
Physical properties
Polymer Sciences
Polyvinylidene fluorides
Pressing
Rechargeable batteries
Renewable and Green Energy
Research Article
Spinning (materials)
Textile Engineering
Wearable computers
Wet spinning
Xanthan
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Summary:Cable/fiber-shaped Zn-ion batteries are designed to power wearable electronics that require high flexibility to operate on human body. However, one of technical challenges of these devices is the complexity and high cost for manufacturing fibered cathode. In this work, we demonstrated gamma manganese oxide (ɣ-MnO 2 )/reduced graphene oxide (rGO) fibered cathode fabrication using facile and cost-effective fiber production and active material coating techniques. Specifically, rGO fibers were fabricated via wet spinning, followed by chemical reduction with hydroiodic acid (HI). The synthesized rGO fiber bundle was then dip-coated with a mixture of ɣ-MnO 2 , carbon black or multi-walled carbon nanotubes, and xanthan gum or polyvinylidene fluoride binder to obtain ɣ-MnO 2 /rGO fibered cathode. We studied the effect of binders and conductive materials on physical properties and electrochemical performance of the fibered cathode. It was found that hydrophobic binder had more benefits than hydrophilic binder by providing higher active material loading, better coating layer homogeneity, and more stable electrochemical performance. Cable-shaped Zn-ion batteries (CSZIBs) were then assembled by using the ɣ-MnO 2 /rGO fibered cathode, Zn wire anode, and xanthan gum polymeric gel electrolyte with 2 M ZnSO 4 and 0.2 M MnSO 4 salts without a separator. We investigated the battery assembling procedure on a glass slide (prototype ZIB) and in a plastic tube (cable-shaped ZIB), and evaluated their electrochemical performance. The CSZIB showed promising maximum capacity of ~ 230 mAh/g with moderate cycling stability (80% capacity retention after 200 cycles) and high flexibility by maintaining the potential after consecutive pressing for 200 times under controlled pressing distance, duration, and testing speed. Finally, we explored ion intercalation behaviours and proposed a H + /Zn 2+ co-intercalation mechanism in ZIB with ɣ-MnO 2 active material. Graphical abstract
ISSN:2524-7921
2524-793X
DOI:10.1007/s42765-021-00118-3