Contents I. Introduction
Admittance spectroscopy (AS) is a powerful technique to understand the defect properties, such as the energy level, defect density of states (DOS), and their capture-cross section, from the AC response of semiconductor devices [1]. Admittance spectroscopy is commonly used to characterize the defects properties of inorganic semiconductor materials such as cadmium telluride (CdTe) [2], and, lately, in organic solar cells and perovskite solar cells (PSCs) [3]. However, determining the appropriate properties of the defects with the applied frequency and temperature of the experiment is one of the essential requirements for proper defect evaluation by admittance spectroscopy. The defect level (Et) of a p-type semiconductor that locates inside the bandgap bends below the Fermi level (EF) in the depletion region. The occupation status of the defect state can be changed as a response to the applied AC voltage (VAC) at a certain temperature, i.e., the defect state can be filled and emptied from the charge, thus, contributing to the measured capacitance. Note that there is no charging or discharging and no contribution to the capacitance outside the depletion region where Et is above EF, because the defect state cannot be filled. Additionally, the defects that have enough thermal ionization energy can only keep up with the applied AC voltage and contribute to the capacitance if the emission rate of the defect state () is higher than the applied angular frequency () of the AC voltage, . However, if the emission rate of electrons is lower than the frequency of AC bias, they will not follow external bias and cannot contribute to the capacitance.
