Performance analysis and economic competiveness of 3 different PV technologies for hydrogen production under the impact of arid climatic conditions of Morocco

Abstract

For green hydrogen production, the choice of the appropriate renewable energy source to drive the water electrolysis process is crucial. Currently, solar Photovoltaic (PV) energy is one of the most popular and cheapest renewable energy sources; however, the performance of this technology is highly affected by the weather condition especially after the exposition to harsh climate conditions for long periods. Accordingly, the aim of this study is to assess the appropriate PV technology for hydrogen production under the impact of arid climatic conditions. For this reason, we evaluated the hydrogen production from 3 PV technologies, namely: monocrystalline (m-Si), polycrystalline (p-Si) and amorphous (a-Si) technologies exposed outdoors for a period of 3 years under the arid climatic conditions of Errachidia, Morocco. In addition, the degradation rate of each technology has been calculated and its impact on hydrogen production and its cost has been investigated.The results show that, the technology with the higher yearly hydrogen yield is the p-Si with 37.07 kg/kWp, followed by the m-Si with 36.84 kg/kWp and finally the a-Si with 36.68 kg/kWp. As for the cost of hydrogen production, the lowest cost was found in the case of the p-Si technology as well with 4.89 $/kg, whereas for the m-Si and a-Si technologies it was found equal to 5.48 $/kg and 6.28 $/kg respectively. However, the evaluation the impact of the PV modules degradation reveals that p-Si is technology affect the most with an annual degradation rate of 0.92%, followed by the a-Si with 0.72% and m-Si technologies with 0.45%. Nonetheless, when taken in consideration the impact of the degradation on the cost of hydrogen production, the p-Si remain the most cost effective technology even though the cost has increase to 5.32 $/kg, 5.78 $/kg and 6.67 $/kg for the p-Si, m-Si and a-Si technologies respectively.