Mixed-halide perovskites (MHPs) have attracted attention as suitable wide-band-gap candidate materials for tandem applications owing to their facile band-gap tuning. However, when smaller bromide ions are incorporated into iodides to tune the band gap, photoinduced halide segregation occurs, which leads to voltage deficit and photoinstability. Here, we propose an original post-hot pressing (PHP) treatment that suppresses halide segregation in MHPs with a band gap of 2.0 eV. The PHP treatment reconstructs open-structured grain boundaries (GBs) as compact GBs through constrained grain growth in the in-plane direction, resulting in the inhibition of defect-mediated ion migration in GBs. The PHP-treated wide-band-gap (2.0 eV) MHP solar cells showed a high efficiency of over 11%, achieving an opencircuit voltage (V oc ) of 1.35 V and improving the maintenance of the initial efficiency under the working condition at AM 1.5G. The results reveal that the management of GBs is necessary to secure the stability of wide-band-gap MHP devices in terms of halide segregation.
The
transient properties of photogenerated carriers using a pulsed
laser have been widely used to observe carrier characteristics of
perovskite solar cells (PSCs). However, these transient results could
not reveal a steady-state operation performance of the PSCs under
continuous illumination. Thus, an evaluation of the transporting parameters
for perovskite thin films (PTFs) under continuous illumination is
needed to understand the operation performance of solar cells. Here,
we report that the steady-state transport parameters for the PTF can
be extracted through photo-Hall effect measurement (PHEM) by solving
the signal uncertainty. We observed that the interaction of atmospheric
gas molecules with the PTF causes the uncertainty of opto-electrical
results. The uncertainty of signals was overcome by designing a Hall
specimen and controlling the surface of the PTF. We characterized
two types of PTFs featuring distinct efficiency differences and successfully
extracted their transporting parameters in the near-1-sun conditions
through the PHEM.
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