Fabrication of binder-free SnO2 nanoparticle electrode for lithium secondary batteries by electrophoretic deposition method

[Display omitted] ► The co-deposited film consisting of nano-SnO2 and AB was fabricated by an EPD method. ► Close-up photograph of front of the co-deposited film is shown in part (a). ► The co-deposited film can withstand from an external force as shown in part (b). ► The EPD method is useful to fab...

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Bibliographic Details
Published in:Electrochimica acta 2012-08, Vol.76, p.383-388
Main Authors: Ui, Koichi, Kawamura, Soshi, Kumagai, Naoaki
Format: Article
Language:English
Subjects:
Binder free
Electrophoretic deposition method
Lithium secondary battery
Negative electrode
SnO2 nanoparticle
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Summary:[Display omitted] ► The co-deposited film consisting of nano-SnO2 and AB was fabricated by an EPD method. ► Close-up photograph of front of the co-deposited film is shown in part (a). ► The co-deposited film can withstand from an external force as shown in part (b). ► The EPD method is useful to fabricate an electrode using nanoparticles. ► The binder-free co-deposited film operates well as a negative electrode. We tried fabricating a binder-free co-deposited film electrode consisting of SnO2 nanoparticles (nano-SnO2) and acetylene black (AB) particles by an electrophoretic deposition (EPD) method. By cathodically depositing on a copper foil when employing an acetone bath, the co-deposited film consisting of nano-SnO2 and AB could be fabricated. SEM/EDX indicated that the roughness of the co-deposited film was approximately 1μm and the nano-SnO2 particles and the AB particles were uniformly deposited. The weight percent of the nano-SnO2 in the co-deposited film could be controlled in the range from 87.80 to 93.64wt.%. The galvanostatic charge–discharge tests indicated that the discharge capacity and the charge–discharge efficiency of the co-deposited film (nano-SnO2:AB=93.64:6.36wt.%) at the 1st cycle were 887mAhg−1 and 48.8% at 0.1C, respectively; the discharge capacity after the 50th cycle was 504mAhg−1. It has been considered that the reverse reaction of the conversion reaction would occur during discharging because the discharge capacity at the 1st cycle was higher than the theoretical capacity of SnO2 (783mAhg−1). Thus it has been clarified that the binder-free co-deposited film could operate as a negative electrode for lithium secondary batteries.
ISSN:0013-4686
1873-3859
DOI:10.1016/j.electacta.2012.05.048