University of Tsukuba researchers examine the molecular-level processes taking place in perovskite solar cells when they are operating, to determine the factors that affect their performance.
The team explained that focusing on improving PCEs alone could be causing researchers to miss the significant steps forward that might result from a more detailed understanding of the underlying mechanisms. For example, the question of what causes the performance of perovskite solar cells to deteriorate is an important one that has not been comprehensively answered. External factors such as oxygen and moisture in the air are known to compromise perovskite layers. However, the internal changes that affect the performance of cells are not as well understood. The researchers have therefore probed the deterioration mechanism using electron spin resonance (ESR) spectroscopy.
"We carried out ESR spectroscopy on perovskite solar cells while they were in use, which gave us a real-time picture of the molecular-level changes," study corresponding author Professor Kazuhiro Marumoto explains. "Specifically, we observed the charges and defects, and related spin states, in the solar cell layers while the current-voltage characteristics of the solar cells were being measured. This allowed us to understand the relationships between these factors."
This in-depth investigation of perovskite solar cells in operation showed that changes in the spin states result from changes in hole transport as well as the formation of interfacial electric dipole layers. It was therefore concluded that cell deterioration could be prevented by improving charge mobility in the hole transport material and preventing electric dipole layer formation.
"Establishing that changes in spin states are correlated with device performance has significantly broadened our understanding of perovskite solar cells," Professor Marumoto says. "We hope that our findings will provide a valuable new starting point for the continued development of solar cells and help accelerate the reality of cost-effective green energy."