Overcoming the limit of capacitance in Bi based supercapacitors by functionalizing their electrodes with NH4Bi3F10 cubes

In this research, flexible supercapacitors (SCs) were made with carbon nanotube fibers and NH4Bi3F10 (NBiF) particles. According to the analysis by microscopy, the NBiF consisted in a mixture of particles with irregular/cubic morphology. The cubic particles have lateral sides in the range of 170–115...

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Bibliographic Details
Published in:Synthetic metals 2023-04, Vol.294, p.117315, Article 117315
Main Authors: Balderas-Soto, M., Vazquez-Lepe, M., Martinez-Gomez, A. de J., Gomez-Solis, C., Mtz-Enriquez, A.I., Oliva, J.
Format: Article
Language:English
Subjects:
Bismuth
Carbon nanotubes
Energy density
NH4Bi3F10
Supercapacitor
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Summary:In this research, flexible supercapacitors (SCs) were made with carbon nanotube fibers and NH4Bi3F10 (NBiF) particles. According to the analysis by microscopy, the NBiF consisted in a mixture of particles with irregular/cubic morphology. The cubic particles have lateral sides in the range of 170–1150 nm. SC devices made with and without NBiF particles were named CNBi-SC and CN-SC, respectively. The CNBi-SC device showed a capacitance of 818.2 F g-1 and energy density of 113.6 Wh kg-1. In contrast, the CN-SC device had a lower capacitance and energy density values of 203.7 F g-1 and 28.3 Wh kg-1, respectively. Thus, adding the NBiF particles on the SC electrodes increased the capacitance and energy density by ≈ 300%. In addition, the SCs made with and without NBiF were subjected to 500 bending or charging/discharging cycles and their capacitance retention was calculated. Despite the stressing conditions, the capacitance retention was in the range of 90–94% for the CNBi-SC device, but it was lower for the for the CN-SC device (82–85%). Raman, XPS and optical analyses demonstrated the presence of oxygen vacancy defects and Bi2+/Bi3+ species. Those ones were responsible of the redox reactions for the storage of charge. The analysis by impedance spectroscopy revealed that the series and charge transfer resistances decreased after the introduction of the NBiF particles in the SC electrodes, which facilitated the ion transfer from the electrolyte to the electrodes. Hence, the results presented here could pave the way for the improvement of SCs made with low-cost Bi compounds. [Display omitted] •Electrodes of CNTs+NH4Bi3F10 (NBiF) were employed for solid-state SCs.•The capacitance was enhanced ≈ 4 times after introducing NBiF in the SC electrodes.•A maximum capacitance of 818.2 Fg-1 was produced in the device made with NBiF.•Capacitance retention ≥ 90% were obtained despite charging/discharging or bending cycles.•Bi2+/Bi3+ and oxygen vacancies defects were the redox centers for the charge storage.
ISSN:0379-6779
1879-3290
DOI:10.1016/j.synthmet.2023.117315