Photovoltaics is a key technology in efforts to decarbonize the energy supply. Solar cells using based on perovskite semiconductor layers already boast very high efficiency levels. They can be produced economically in thin and flexible designs. “Perovskite photovoltaics is at the threshold of commercialization but still faces challenges in long-term stability and scaling to large surface areas,” said Professor Ulrich Wilhelm Paetzold, a physicist who performs conducts research at the Institute of Microstructure Technology and the Light Technology Institute (LTI) at KIT. “Our research shows that machine learning is crucial to improving the monitoring of perovskite thin-film formation that’s needed for industrial production.” With deep learning (a machine learning method that uses neural networks), the KIT researchers were able to make quick and precise predictions of solar cell material characteristics and efficiency levels at scales exceeding those in the lab.
A Step toward Industrial Viability
“With measurement data recorded during production, we can use machine learning to identify process errors before the solar cells are finished. We don’t need any other examination methods,” said Felix Laufer, an LTI researcher and lead author of the paper. “This method’s speed and effectiveness are a major improvement for data analysis, making it possible to solve problems that would otherwise be very difficult to deal with.”
By analyzing a novel dataset documenting the formation of perovskite thin films, the researchers leveraged used deep learning to identify correlations between process data and target variables such as power conversion efficiency.
“Perovskite photovoltaics has the potential to revolutionize the photovoltaics market,” said Paetzold, who heads the LTI’s Next Generation Photovoltaics department. “We show how process fluctuations can be quantitatively analyzed with characterization methods enhanced by machine learning techniques to ensure high material quality and film layer homogeneity across large areas and batch sizes. This is a crucial step toward industrial viability.”
Original publication
Felix Laufer, Markus Götz, and Ulrich W. Paetzold: Deep learning for augmented process monitoring of scalable perovskite thin-film fabrication. DOI: 10.1039/D4EE03445G
Being “The Research University in the Helmholtz Association”, KIT creates and imparts knowledge for the society and the environment. It is the objective to make significant contributions to the global challenges in the fields of energy, mobility, and information. For this, about 10,000 employees cooperate in a broad range of disciplines in natural sciences, engineering sciences, economics, and the humanities and social sciences. KIT prepares its 22,800 students for responsible tasks in society, industry, and science by offering research-based study programs. Innovation efforts at KIT build a bridge between important scientific findings and their application for the benefit of society, economic prosperity, and the preservation of our natural basis of life. KIT is one of the German universities of excellence.
Computational simulation/modeling
Not applicable
Deep learning for augmented process monitoring of scalable perovskite thin-film fabrication
7-Jan-2025