Abstract
This study investigated the structural, electrical, and optical properties of MoS(2) and Co-doped MoS(2) nanosheets, focusing on their potential applications in optoelectronics. High-resolution transmission electron microscopy (HRTEM), X-ray diffraction (XRD), current-voltage (I-V), and ultraviolet-visible (UV-vis) spectroscopy were used to examine the materials. Results indicate that Co-doping enhances the active sites for more light absorption, reduces the bandgap, and improves photoconductivity. The diode characteristics from I-V measurements were also analyzed. The I-V showed typical diode-like rectification behavior with great improvement in key parameters like the ideality factor (n), saturation current (I (s)), and junction resistance (R (j)) of the Co-doped device. The photodetector based on the Co-doped device exhibited superior photocurrent (I (photo)) generation, responsivity (R), and detectivity (D*) compared to the MoS(2) device, indicating its enhanced photodetection performance. These results show that Co-doping significantly improves the efficiency of photon-to-electron conversion, making the MoS(2)-Co device much more efficient in harvesting light energy.