2D molybdenum disulfide has great potential for use in advanced electronic and optoelectronic devices because of its unique properties. Due to the layered structure of MoS2, it is possible to control the electronic properties by varying the number of layers. This material has shown advantages in gas sensors such as a low detection limit. However, the stability of its characteristics needs improvement. One common method for creating 2D structures is mechanical exfoliation, which has low reproducibility. A different method used in this study is hydrothermal synthesis.

Sodium molybdate dihydrate, oxalic acid dihydrate and thiourea were used as precursors. The precursors were dissolved in distilled water and placed in an autoclave for 14 hours at 200°C. Chemical exfoliation of the produced particles was performed using zinc nitrate hexahydrate and hydrochloric acid. The nanoparticles were analyzed using scanning electron microscopy and X-ray photoelectron spectroscopy. The resulting powders were deposited onto sensor platform by spin-coating.

The gas-sensitive properties were studied using impedance spectroscopy. Sensitivity to isopropyl alcohol vapors was studied at room temperature, at different gas concentrations. The value of the sensor response was calculated using the formula for the real and imaginary components separately. It was found that, when 500 ppm of isopropyl alcohol vapor was applied, the maximum response in the real component was 2.6. With an increase in frequency above 4 kHz a decrease in sensitivity was observed. For the imaginary component, the maximum value was 5.3. A decrease in sensitivity is observed after 9kHz. The same parameters were measured at concentrations of 1000 ppm and 2000 ppm.

Thus, MoS₂ flower-like nanoparticles were synthesized using the hydrothermal method. By impedance spectroscopy, it was shown that the produced sensor layers can detect volatile organic compounds in air at room temperature.