Dielectric spectroscopy is a broadly involved procedure for exploring the electrical properties of materials. In this review, we utilized dielectric spectroscopy to look at the recurrence subordinate way of behaving of an example material. The research's objective was to learn more about the material's molecular dynamics and relaxation processes. We led estimations over an expansive recurrence range, going from low frequencies to a few gigahertz, using both impedance and capacitance estimations. A precise impedance analyzer and carefully designed sample cells made up the experimental setup. The material must have multiple dynamic modes, as our findings revealed distinct relaxation processes in various frequency regimes. By dissecting the dielectric spectra, we had the option to separate significant data about the unwinding times, actuation energies, and atomic elements of the framework. These discoveries add to a more profound comprehension of the material's electrical way of behaving and have likely ramifications in different fields, including materials science, science, and science. In general, this study demonstrates the versatility of dielectric spectroscopy as a method for defining the electrical properties and dynamics of materials.