PHOTOVOLTAIC CHARACTERISTICS AND THEIR RELATIONSHIP WITH THE DEFECT STATES IN PEROVSKITE SOLAR CELLS
The presence of defect states in perovskite solar cells affects their performance and stability. Defect states in perovskite solar cells arise due to the rapid perovskite crystallization and low-temperature process. In addition, perovskite crystals are dominated by ionic bonds which are quite wea...
Saved in:
| Main Author: | |
|---|---|
| Format: | Dissertations |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/79520 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The presence of defect states in perovskite solar cells affects their performance and
stability. Defect states in perovskite solar cells arise due to the rapid perovskite
crystallization and low-temperature process. In addition, perovskite crystals are
dominated by ionic bonds which are quite weak compared to the covalent bonds in
silicon solar cells, causing the possibility of various types of crystal defects such as
vacancies, interstitial defects, lattice distortion by accumulated charges, and
dissolved impurities. These various types of defects form deep and shallow traps
that affect solar cell performance, so it is necessary to understand the mechanism
and how far these defects affect solar cell performance.
In this study, perovskite solar cells were made with a mesoscopic structure
consisting of FTO/(TiO2 compact) c-TiO2/TiO2 mesopori (mpTiO2)/MAPbI3/PTAA/Emas (Au) layers. This research aims to observe the kinetics
of transport and extraction of charge carriers by measuring transient photovoltage
(TPV), to see the correlation between electronic processes, which can be affected
by defect states caused by the characteristics of the mesoscopic structure of
perovskite layers, and solar cell performance. In addition, a correlation study of
solar cell performance and impedance characteristics obtained from Intensity
Modulated Photovoltage Spectroscopy (IMVS) measurements was also carried out,
which aims to understand the impact of charge carrier kinetics and ionic motion,
due to surface or interface defects of the perovskite layer, on cell performance.
Based on the research that has been done, the results show that the characteristics
of the TPV curve show different characters for several fabricated cells. The
observed TPV curve consists of a rise part and a decay part. The rise part is related
to the cargo transport process, while the decay part is related to the recombination
process in the perovskite layer with the transport layer. The elongated decay part
indicates that there are more surface states in the perovskite/transport layer which
causes trapping and detrapping of electrons. So the electrons take longer to reach
the valence band of the perovskite layer.
From this TPV measurement it is also found that the decay curve is a
multiexponential decay consisting of fast decay, medium decay and slow decay. Fast decay with stretching exponential decay characteristics indicates the presence
of non-simple first-order trapping and recombination processes that involve multitrapping processes including electron transport at the crystalline grain surface or
interface. This fast decay is also related to the relaxation of structural surface
defects, where this fast decay correlates with the appearance of semicircles in the
low frequency region of the Nyquist plot of the IMVS measurement associated with
ion migration or separation. In this study also used the passivation molecule TFA
to reduce the effects of crystal defects that occur during manufacture, storage and
when the cell is operating. The results show that cells with 5% TFA have the least
trap density compared to other cells. In addition, measurements of cell efficiency
on the fourth day after preparation showed that cells with TFA had better
performance stability than cells without TFA. These results indicate that the TFA
passivation molecule has the potential to be one of the candidate molecules that
can be used to reduce the effects of the defective state in perovskite solar cells. |
|---|