Electronic Properties of Transition and Alkaline Earth Metal Doped CuS: A DFT Study

CuS is a unique semiconductor with potential in optoelectronics. Its unusual electronic structure, including a partially occupied valence band, and complex crystal structure with an S-S bond offer unique opportunities and potential applications. In this work, the use of doping to optimize the properties of CuS for various applications is investigated by density functional theory (DFT) calculations. Among the dopants studied, Ni, Zn, and Mg may be the most practical due to their lower formation energies. Doping with Fe, Ni, or Ca induces significant distortion, which may be beneficial for achieving materials with high surface areas and active states. Significantly, doping alters the conductor-like behavior of CuS, opening a band gap by increasing bond ionicity and reducing the S-S bond covalency. Thus, doping CuS can tune the plasmonic properties and transform it from a conductor to an intrinsic fluorescent semiconductor. Ni and Fe doping give the lowest band gaps (0.35 eV and 0.39 eV, respectively), while Mg doping gives the highest (0.86 eV). Doping with Mg, Ca, and Zn may enhance electron mobility and charge separation. Most dopants increase the anisotropy of electron-to-hole mass ratios, enabling device design that exploits directional-dependence for improved performance. Doping of CuS is shown through density functional theory calculations to allow control of the band gap and semiconductor behavior by changing the bond ionicity. Doping with Mg, Ca, and Zn may also enhance electron mobility and charge separation.image

Automated summary

CuS is a unique semiconductor with potential in optoelectronics. Doping with various elements can optimize its properties, including band gap and conductivity behavior. Doping can also alter the plasmonic properties, electron mobility, and charge separation. The use of dopants such as Ni, Zn, Mg, Fe, and Ca can effectively tune the properties of CuS for different applications.