Novel perovskite solar cell with Distributed Bragg Reflector

This paper reports numerical modeling of perovskite solar cell which has been knotted with Distributed Bragg Reflector pairs to extract high energy efficiency. The geometry of the proposed cells is simulated with three different kinds of perovskite materials including CH3NH3PbI3, CH3NH3PbBr3, and CH3NH3SnI3. The toxic perovskite material based on Lead iodide and lead bromide appears to be more efficient as compared to non-toxic perovskite material. The executed simulated photovoltaic parameters with the highest efficient structure are open circuit voltage = 1.409 (V), short circuit current density = 24.09 mA/cm(2), fill factor = 86.18%, and efficiency = 24.38%. Moreover, a comparison of the current study with different kinds of structures has been made and surprisingly our novel geometry holds enhanced performance parameters that are featured with back reflector pairs (Si/SiO2). The applied numerical approach and presented designing effort of geometry are beneficial to obtain results that have the potential to address problems with less efficient thin-film solar cells.

Automated summary

This study presents numerical modeling of perovskite solar cells with Distributed Bragg Reflector pairs, comparing the efficiency of toxic perovskite materials with non-toxic ones. The simulated photovoltaic parameters of the most efficient structure showed promising results, outperforming other structures. The applied numerical approach and novel geometry design hold potential for addressing issues with less efficient thin-film solar cells.