In our current study, we have investigated the effect of potassium doping on AC conductivity and the dielectric properties of tin selenide (SnSe). Potassiumdoped SnSe (K x Sn 1-x Se with x = 0-20 mol%) polycrystals were synthesized via hydrothermal method. The phase of the synthesized samples was confirmed to be single phase with orthorhombic structure as obtained by X-ray diffraction. The average crystallite size for all the K x Sn 1-x Se samples was calculated using the Debye-Scherrer formula and they were found to be decreased as potassium (K) concentration increased. Scanning electron microscope revealed plate-like morphology for all K x Sn 1-x Se samples. Transmission electron microscope studies at high resolution showed plate-like morphology which is connected with small nanorods for the K 0.20 Sn 0.80 Se. Optical studies were carried out using UV-Vis-NIR diffuse reflectance spectroscopy. The bandgap values were found to be decreased as K concentration is increased. Temperature-dependent dielectric studies were studied for all K x Sn 1-x Se samples. Correlated barrier hopping is responsible for the transport of charge carriers in the conduction mechanism. Electrical modulus studies reveal a non-Debye-type dielectric relaxation phenomenon. The results of dielectric studies specify the application of K-doped SnSe in frequency related and capacitive storage devices.
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