Abstract
The properties of efficient solar cells fabricated with triple-cation perovskite placed between a mesoporous titania layer and a spiro-OMeTAD layer are studied by using devices either prepared under water-free drybox conditions or fabricated under ambient room humidity. The morphological studies indicate that the content of unreacted PbI2 phase in the perovskite structure is much higher near the interface with titania than near the interface with spiro-OMeTAD. The stationary emission spectra and transient bleach peaks of perovskites show additional long-wavelength features close to the titania side. Time-resolved techniques ranging from femtoseconds to seconds reveal further differences in charge dynamics at both interfaces. The population decay is significantly faster at the titania side than at the spiro-OMeTAD side for the cells prepared under ambient conditions. An increased hole injection rate correlates with higher photocurrent seen in the devices prepared under drybox conditions. The charge recombination loss on the millisecond time scale is found to be slower at the interface with titania than at the interface with spiro-OMeTAD. The ideality factor of the cells is found to increase with increasing DMSO content in the precursor solution, indicating a change in recombination mechanism from bulk to surface recombination. We also found that the charge dynamics are not uniform within the whole perovskite layer. This feature has significant implications for understanding the operation and optimizing the performance of solar devices based on mixed cation perovskites.
Highlights
Perovskite solar cells (PSCs) have undergone a tremendous increase in efficiency from 3.8% in 20091 to an outstanding 25.2% certificated only 10 years later in 2019.2 The initial and the most studied perovskite structure for PSC is methylammonium lead triiodide (MAPbI3).[1]
The triple-cation perovskite solar cells were prepared by two methods: under drybox conditions (DC) or under ambient air conditions (AC), as described in the Materials and Methods section
The results are verified for perovskite solar cells prepared with standard procedure under water-free drybox conditions as well as those fabricated under ambient room humidity
Summary
Perovskite solar cells (PSCs) have undergone a tremendous increase in efficiency from 3.8% in 20091 to an outstanding 25.2% certificated only 10 years later in 2019.2 The initial and the most studied perovskite structure for PSC is methylammonium lead triiodide (MAPbI3).[1]. Most fundamental studies of PSCs are still mainly limited to the standard MAPbI3 structure
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