Opto-Electro-Thermal Modeling of Thin-Film Hydrogenated Amorphous Silicon (a-Si:H) Photovoltaic Cell

A one-dimensional opto-electro-thermal simulator for an a-Si:H-based thin-film solar cell is developed. The simulator includes optical, electrical, and thermal modeling for a complete modeling of energy conversion in a-Si:based solar cells. Particularly, the thermal impact on the performance of the cell has been studied. Cell performance is worse when thermal simulation is included compared to simulations where the temperature is kept constant. This implication suggests that cell performance is typically overestimated in simulations where the thermal effect is ignored. A simplified optical model was used, reducing the computational resources required in the study. The electrical model proposed in this study extends the classical drift-diffusion model to include the effects of temperature. The proposed thermal model considers the energy conservation in a non-thermal equilibrium condition between electron, optical phonons, and acoustic phonons. While simplifications have been used to reduce the complexity of the simulations, the program captures the essential behavior of the cell with reasonable accuracy. Hence, the developed program is useful for a-Si:H-based thin-film solar cell design and optimization.

Automated summary

A one-dimensional opto-electro-thermal simulator for an a-Si:H-based thin-film solar cell has been developed, incorporating optical, electrical, and thermal modeling for energy conversion analysis. The study shows that cell performance is typically overestimated when the thermal effect is ignored. Despite simplifications, the program accurately captures the essential behavior of the cell, proving useful for design and optimization of a-Si:H-based thin-film solar cells.