The effect of formation temperature and flexo-chemical strains on the electrophysical properties of the molybdenum-disulfide-oxide nanoflakes

The effect of formation temperature and flexo-chemical strains on the electrophysical properties of the molybdenum-disulfide-oxide nanoflakes

We synthesized the powder of molybdenum-disulfide-oxide nanoflowers consisting of self-assembled 10-20 nm thin nanoflakes by reaction of (NH4)6Mo7O24 with thiourea in aqueous solution at temperatures from 130oC to 180oC in hydrothermal conditions. The detailed analysis of the XPS, EDX and Raman spec...

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Main Authors: Pylypchuk, Oleksandr S, Vainberg, Victor V, Poroshin, Vladimir N, Terebilenko, Anastasyia V, Nikolenko, Andrii S, Popenko, Vadym I, Tolochko, Anatolyi S, Olenchuk, Maryna V, Bezkrovnyi, Oleksii, Dovbeshko, Galina I, Sabov, Tomash, Romanyuk, Boris M, Morozovska, Anna N, Kolotilov, Sergey V
Format: Journal Article
Language:English
Published: 01-11-2024
Subjects:
Physics - Materials Science
Physics - Mesoscale and Nanoscale Physics
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Summary:We synthesized the powder of molybdenum-disulfide-oxide nanoflowers consisting of self-assembled 10-20 nm thin nanoflakes by reaction of (NH4)6Mo7O24 with thiourea in aqueous solution at temperatures from 130oC to 180oC in hydrothermal conditions. The detailed analysis of the XPS, EDX and Raman spectroscopy results reveal the significant amount of the molybdenum oxides, sulfides and sulfates in the molybdenum disulfide nanoflakes, which allows to consider the "effective" formulae MoSxOy for their chemical composition. The MoSxOy nanoflakes reveal unusual electric transport features interesting for material science and promising for applications. The chemical composition and microstructure of the nanoflakes, which are determined by the temperature of synthesis, is shown to be responsible for the electro-conduction mechanism. Namely, the current-voltage characteristics (I-V curves) grow monotonically with the applied voltage for the samples, synthesized at the temperatures T_s<<150oC and T_s>>150oC, being non-ohmic and hysteretic at lower voltages and becoming close to the ohmic at higher voltages. The I-V curves acquire N-like shape with a strongly pronounced negative differential resistivity part at T_s=150oC. Both with and without N-shape, the I-V curves manifest hysteretic behavior with the difference between increasing and decreasing voltage sweeps, and the hysteresis loop parameters are determined by the temperature of synthesis. Important, that the studied nanoflakes manifest very long living deep charging and discharging after the voltage switching "on" and "off".Considering that the presence of oxygen non-stoichiometry and bending can create strong flexo-chemical strains in the nanoflakes, we proposed the flexo-chemical model of the polar and electro-transport properties of the pressed MoSxOy nanoflakes, which describes the observed I-V curves.
DOI:10.48550/arxiv.2411.00603