Water ingress in encapsulated inverted organic solar cells: Correlating infrared imaging and photovoltaic performance
Adams J, Salvador MF, Lucera L, Langner S, Spyropoulos GD, Fecher F, Voigt M, Dowland SA, Osvet A, Egelhaaf HJ, Brabec C (2015)
Publication Language: English
Publication Status: Published
Publication Type: Journal article, Original article
Publication year: 2015
Journal
Book Volume: 5
Article Number: 1501065
Journal Issue: 20
Abstract
Understanding the degradation and failure mechanisms of organic photovoltaic devices is a key requirement for this technology to mature toward a reliable product. Here, an investigation on accelerated temperature and moisture long-term stability testing (>20 000 h) of inverted and glass-encapsulated poly(3-hexylthiophene)/phenyl-C-butyric acid methyl ester solar cells is presented. The degradation kinetics is analyzed using the Arrhenius model and the resulting activation energy for the diffusion of water is measured to be ≈43 kJ mol. Through comparison of electroluminescence imaging, lock-in thermography, and photoluminescence mapping, the device performance is correlated with the loss of effective cell area and it is shown that the reaction of water at the hole extraction/active layer interface is likely to be the dominant cause for long-term device failure. The diffusion of water through the packaged solar cell is described using classical diffusion theory. Based on an analytical solution of a simple diffusion model, the diffusion coefficient is estimated to be 4 × 10 m s. A shelf life of 100 000 h is anticipated at 65 °C/85% RH using a 9.3 cm wide protective adhesive rim. The findings of this study may inform strategies for predicting lifetimes of organic solar cells and modules based on local in situ tracking of moisture-induced device performance loss using IR imaging. Lifetime limitations of current-generation inverted and encapsulated organic solar cells under damp heat conditions are identified by correlating photovoltaic device performance with lock-in IR imaging techniques. The combination of electroluminescence imaging and water diffusion modeling may inform strategies for predicting early performance losses in solar cells and modules.
Authors with CRIS profile
Michael Filipe Salvador
Institute Materials for Electronics and Energy Technology (i-MEET)
Stefan Langner
Institute Materials for Electronics and Energy Technology (i-MEET)
Frank Fecher
Institute Materials for Electronics and Energy Technology (i-MEET)
Monika Voigt
Institute Materials for Electronics and Energy Technology (i-MEET)
Andres Osvet
Institute Materials for Electronics and Energy Technology (i-MEET)
Christoph Brabec
Institute Materials for Electronics and Energy Technology (i-MEET)
Involved external institutions
Bayerisches Zentrum für Angewandte Energieforschung e.V. (ZAE Bayern)
Germany (DE)
BELECTRIC OPV GmbH
Germany (DE)
Germany (DE)
BELECTRIC OPV GmbH
Germany (DE)
How to cite
APA:
Adams, J., Salvador, M.F., Lucera, L., Langner, S., Spyropoulos, G.D., Fecher, F.,... Brabec, C. (2015). Water ingress in encapsulated inverted organic solar cells: Correlating infrared imaging and photovoltaic performance. Advanced Energy Materials, 5(20). https://dx.doi.org/10.1002/aenm.201501065
MLA:
Adams, Jens, et al. "Water ingress in encapsulated inverted organic solar cells: Correlating infrared imaging and photovoltaic performance." Advanced Energy Materials 5.20 (2015).
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