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Title Investigation of AC Electrical Properties of MXene-PCL Nanocomposites for Application in Small and Medium Power Generation
Authors Kołtunowicz, T.N.
Gałaszkiewicz, P.
Kierczyński, K.
Rogalsk, P.
Okal, P.
Pohrebniak, Oleksandr Dmytrovych  
Buranych, Volodymyr Volodymyrovych
Pohorielov, Maksym Volodymyrovych  
Diedkova, Kateryna Andriivna
Zahorodna, V.
Balitskyi, V.
Serhiienko, V.
Baginskyi, I.
Gogotsi, O.
ORCID http://orcid.org/0000-0002-9218-6492
http://orcid.org/0000-0001-9372-7791
Keywords MXene
MXene-PCL nanocomposites
small and medium power generation
electrical properties
flexible electronics
Type Article
Date of Issue 2021
URI https://essuir.sumdu.edu.ua/handle/123456789/87531
Publisher Centre of Sociological Research in co-operation with University of Szczecin (Poland); Széchenyi István University (Hungary); Mykolas Romeris University (Lithuania); Dubcek University of Trencín, Faculty of Social and Economic Relations (Slovak Republic)
License Creative Commons Attribution 4.0 International License
Citation Czernek, K.; Ochowiak, M.; Janecki, D.; Zawilski, T.; Dudek, L.; Witczak, S.; Krupińska, A.; Matuszak, M.; Włodarczak, S.; Hyrycz, M.; Pavlenko, I. Sedimentation Tanks for Treating Rainwater: CFD Simulations and PIV Experiments. Energies 2021, 14, 7852. https://doi.org/10.3390/en14237852
Abstract The paper examined Ti3C2Tx MXene (T—OH, Cl or F), which is prepared by etching a layered ternary carbide Ti3AlC2 (312 MAX-phase) precursor and deposited on a polycaprolactone (PCL) electrospun membrane (MXene-PCL nanocomposite). X-ray Diffraction analysis (XRD) and Scanning Electron Microscopy (SEM) indicates that the obtained material is pure Ti3C2 MXene. SEM of the PCL-MXene composite demonstrate random Ti3C2 distribution over the nanoporous membrane. Results of capacitance, inductance, and phase shift angle studies of the MXene-PCL nanocomposite are presented. It was found that the frequency dependence of the capacitance exhibited a clear sharp minima in the frequency range of 50 Hz to over 104 Hz. The frequency dependence of the inductance shows sharp maxima, the position of which exactly coincides with the position of the minima for the capacitance, which indicates the occurrence of parallel resonances. Current conduction occurs by electron tunneling between nanoparticles. In the frequency range from about 104 Hz to about 105 Hz, there is a broad minimum on the inductance relationship. The position of this minimum coincides exactly with the position of the maximum of the phase shift angle—its amplitude is close to 90°. The real value of the inductance of the nanocomposite layer was determined to be about 1 H. It was found that the average value of the distance over which the electron tunnels was determined with some approximation to be about 5.7 nm and the expected value of the relaxation time to be τM ≈ 3 × 10−5 s.
Appears in Collections: Наукові видання (ЕлІТ)

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