This study investigates the electronic conductivity tensor (ECT) of silver iodide (AgI2) quantum dots (QDs) and the impact of metal impurities (Cu, Ni, Zn) on their optoelectronic properties, utilizing density functional theory (DFT) and the Kubo-Greenwood formalism. Pristine AgI2 exhibits a calculated band gap of 2.2 eV and an Ag-I bond length of 2.83 Å, demonstrating anisotropic electrical conductivity. Singularities in the imaginary part of the ECT at 4.3 and 5 eV indicate resonant responses to specific frequencies, potentially enhancing optical conductivity as well as absorption and emission. The incorporation of Cu as AgCuI2 results in a modified ECT spectrum with peak shifts and increased imaginary components, suggesting improved optical conductivity and sensitivity to electric fields, which is beneficial for optical sensor applications. Furthermore, doping with Ni and Zn was also explored. Bond lengths for Ag-Ni, I-Ni, Ag-Zn, and I-Zn are 3.19 Å, 2.98 Å, 3.18 Å, and 3.09 Å, respectively, while band gaps for AgNiI2 and AgZnI2 are 1.49 eV and 1.68 eV, respectively, which are lower compared to AgI2. AgNiI2 and AgZnI2 exhibited enhanced ECT, with AgZnI2 showing the most significant improvement in tensor elements. Overall, the findings highlight the significant tunability of AgI2 QD optoelec�tronic properties through impurity engineering, providing pathways for tailoring materials for specific appli�cations in optoelectronics and solar energy.
