Evaluation of the Electrical Properties of MnO/ZnO:Zn Thin-Films for Potential Applications in Solid-State Supercapacitors

In this work, a bi-layer MnO/ZnO:Zn structure with an approximate thickness of 100 nm for each layer has been successfully synthesized by sputtering. Changes in the electrical properties were evaluated for the potential application for solid-state capacitors as electrodes. The characterization of th...

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Bibliographic Details
Main Authors: Neri-Espinoza, Karen A., Dominguez-Crespo, Miguel A., Andraca-Adame, Jose A., Pena-Sierra, Ramon
Format: Conference Proceeding
Language:English
Subjects:
Automatic frequency control
Capacitors
Electric potential
Electrodes
MnO
Solid-State
Sputtering
Supercapacitor
Supercapacitors
X-ray scattering
ZnO
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Summary:In this work, a bi-layer MnO/ZnO:Zn structure with an approximate thickness of 100 nm for each layer has been successfully synthesized by sputtering. Changes in the electrical properties were evaluated for the potential application for solid-state capacitors as electrodes. The characterization of the layers is carried out through X-Ray Diffraction (XRD), which provides valuable insights into the structural properties. An electrical study employing Frequency Response Analysis (FRA), Bode plots, Voltagetime (V-t), and Current-Voltage (I-V) graphs is conducted to thoroughly examine and understand the electrical behavior of the synthesized layers. XRD results show a MnO phase for the Mn sputtered layer and a mild distortion of the ZnO lattice for the ZnO:Zn co-sputtered layer due to Zn atoms. The electrical study provides a Bode plot where at f100 KHz. At the cutoff frequency (fc) a capacitance value of 142 pF is calculated. The attenuation and reactance effects are also showed in the V-t and I-V graphs. Finally, the time constant (τ) is calculated with a square +5V input signal where also a value of capacitance is obtained as 134 pF, indicating a ±10% of tolerance for the value of capacitance at high frequencies (f≥500 KHz) for the film, where reactance effects can be improved with several MnO/ZnO:Zn nanostructures as electrodes in series to add the capacitor value revealing a potential application for the structure for solid-state supercapacitors.
ISSN:2642-3766
DOI:10.1109/CCE60043.2023.10332869