posted on 2015-12-17, 06:40authored byMiguel Anaya, Gabriel Lozano, Mauricio
E. Calvo, Wei Zhang, Michael B. Johnston, Henry J. Snaith, Hernán Míguez
Herein
we describe both theoretically and experimentally the optical
response of solution-processed organic–inorganic halide perovskite
solar cells based on mesostructured scaffolds. We develop a rigorous
theoretical model using a method based on the propagation of waves
in layered media, which allows visualizing the way in which light
is spatially distributed across the device and serves to quantify
the fraction of light absorbed by each medium comprising the cell.
The discrimination between productive and parasitic absorption yields
an accurate determination of the internal quantum efficiency. State-of-the-art
devices integrating mesoporous scaffolds infiltrated with perovskite
are manufactured and characterized to support the calculations. This
combined experimental and theoretical analysis provides a rational
understanding of the optical behavior of perovskite cells and can
be beneficial for the judicious design of devices with improved performance.
Notably, our model justifies the presence of a solid perovskite capping
layer in all of the highest efficiency perovskite solar cells based
on thinner mesoporous scaffolds.