Perovskite Based Photovoltaic Materials for High Efficiency Solar Harvesting

¹ *Assistant Professor, Department of CS & IT, Kalinga University, Raipur, India
² Assistant Professor, Department of CS & IT, Kalinga University, Raipur, India

^* Corresponding author: ku.AdilRaja@kalingauniversity.ac.in

Abstract

Potentially game-changing innovations include fundamentally novel photovoltaic materials that effectively convert solar energy into usable form via their one-of-a-kind chemical structures and combinations, inexpensive preparation, and laser-targeted chemistry modification. This research presents a stringent methodology for enhancing the Power Conversion Efficiency (PCE) of perovskite cells. Sharing a brilliant idea with the audience is one thing, but for everyone else, it’s just another piece of the puzzle. The PCE equation, the correctly adapted equation for the absorption of solar radiation connected to the individual and cumulative prism approach, and the estimation of the Shockley-Queisser limit are all utilized in system performance modelling, as are certain detailed traditional methods. The practical results have shown that the predicted theory is useful for making sure these numbers are correct. It has been shown in this paper that bandgap engineering of perovskite materials can reach a maximum PCE of 25% at 1.35 eV, and this has been confirmed by testing and modeling. Consistent with theoretical Shockley-Queisser limitations, the results outperform those of traditional silicon cells. To further maximize long-term performance, future work will concentrate on improving device stability, making manufacturing more scalable, and including degradation effects under environmental stress. One technique they will propose is developing reasonable and validated models of perovskite cells and linking them to the rest of the high PCE economic solar cell component.