Investigation into the origin of high stability of δ-MnO2 pseudo-capacitive electrode using operando Raman spectroscopy

Manganese oxides of different structures, especially α-MnO2, have been extensively studied as electrodes for pseudocapacitors. However, the poor stability associated with intercalation of proton has been the main obstacle to their commercial applications. To effectively mitigate this problem, it is...

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Bibliographic Details
Published in:Nano energy 2016-12, Vol.30, p.293-302
Main Authors: Yang, Lufeng, Cheng, Shuang, Wang, Jenghan, Ji, Xu, Jiang, Yu, Yao, Minghai, Wu, Peng, Wang, Mengkun, Zhou, Jun, Liu, Meilin
Format: Article
Language:English
Subjects:
Charge storage mechanism
DFT calculation
in situ Raman spectroscopy
Pseudo-capacitor
δ-MnO2
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Summary:Manganese oxides of different structures, especially α-MnO2, have been extensively studied as electrodes for pseudocapacitors. However, the poor stability associated with intercalation of proton has been the main obstacle to their commercial applications. To effectively mitigate this problem, it is necessary to fully understand the energy storage mechanism of the MnO2 phases. In this study, δ phase MnO2 has been synthesized through controllable electroplating on architectural Ga-doped ZnO (GZO) bones, demonstrating a high specific capacitance of 1068Fg−1 and high stability (slight performance drop focus on the first 2000 cycles and then remained relatively constant in the subsequent 13,000 cycles). The charge storage mechanism of the δ-MnO2 coated GZO has been carefully investigated under this extreme reaction condition. Results suggest that the amount of charge stored in the electrode material correlates well with the amount of Na+ inserted into the electrode material from the electrolyte. It is also noted that no spectral features corresponding to H+ insertion were detected during cycling when the sample was probed using in operando Raman spectroscopy. Therefore, for layered δ-MnO2, a charge storage mechanism of Na+ intercalation/deintercalation dominated, accompanied by interlayer spacing expansion/contraction, was proposed. Moreover, theoretical calculations also confirmed that the insertion of Na+ is more energetically favorable than H+ at all sites of the interlayer in δ-MnO2, offering a rational explanation of the proposed mechanism and the observed excellent stability. MnO2 coated Ga-doped ZnO electrodes demonstrate a specific capacitance of 1068Fg−1 and unprecedented stability in Na2SO4, the charge storage mechanism of which was dominated by an interlayer spacing contraction/expansion due to Na+ intercalation/deintercalation without the involvement of proton, which was illuminated by a joint experimental and theoretical study. [Display omitted] •δ-MnO2 pseudocapacitive electrode demonstrates a high capacitance and stability.•Charge storage mechanism of δ-MnO2 was revealed using operando Raman spectroscopy.•Energy storage is dominated by intercalation/deintercalation of Na+ free of H+.•Adsorption energies of Na+ and H+ in δ-MnO2 were evaluated through DFT computations.
ISSN:2211-2855
DOI:10.1016/j.nanoen.2016.10.018