The study of the inorganic hole-transport layer (HTL)
in perovskite
solar cells (PSCs) is gathering attention because of the drawback
of the conventional PSC design, where the organic HTL with salt dopants
majorly participates in the degradation mechanisms. On the other hand,
inorganic HTL secures better stability, while it offers difficulties
in the deposition and interfacial control to realize high-performing
devices. In this study, we demonstrate polydimethylsiloxane (PDMS)
as an ideal polymeric interlayer which prevents interfacial degradation
and improves both photovoltaic performance and stability of CuSCN-based
PSC by its cross-linking behavior. Surprisingly, the PDMS polymers
are identified to form chemical bonds with perovskite and CuSCN, as
shown by Raman spectroscopy. This novel cross-linking interlayer of
PDMS enhances the hole-transporting property at the interface and
passivates the interfacial defects, realizing the PSC with high power-conversion
efficiency over 19%. Furthermore, the utilization of the PDMS interlayer
greatly improves the stability of solar cells against both humidity
and heat by mitigating the interfacial defects and interdiffusion.
The PDMS-interlayered PSCs retained over 90% of the initial efficiencies,
both after 1000 h under ambient conditions (unencapsulated) and after
500 h under 85 °C/85% relative humidity (encapsulated).
Moving away from the high-performance achievements in organometal halide perovskite (OHP)-based optoelectronic and photovoltaic devices, intriguing features have been reported in that photocarriers and mobile ionic species within OHPs interact with light, electric fields, or a combination of both, which induces both spatial and temporal changes of optoelectronic properties in OHPs. Since it is revealed that the transport of photocarriers and the migration of ionic species are affected not only by each other but also by the inhomogeneous character, which is a consequence of the route selected to deposit OHPs, understanding the nanostructural evolution during OHP deposition, in terms of the resultant structural defects, electronic traps, and nanoscopic charge behaviors, will be valuable. Investigation of the film-growth mechanisms and strategies adopted to realize OHP films with less-defective large grains is of central importance, considering that single-crystalline OHPs have exhibited the most beneficial properties, including carrier lifetimes. Critical factors governing the behavior of photocarriers, mobile ionic species, and nanoscale optoelectronic properties resulting from either or all of them are further summarized, which may potentially limit or broaden the optoelectronic and photovoltaic applications of OHPs. Through inspection of the recent advances, a comprehensive picture and future perspective of OHPs are provided.
Interfacial degradation in perovskite solar cells is a critical issue affecting long-term stability for future commercialization. In particular, a perovskite and an organic hole-transport layer (HTL) react easily when the device is exposed to extreme operating conditions (heat, light, and air). To prevent degradation, an inorganic CuSCN HTL has emerged as an alternative, yet the interfacial reactivity is still not clearly elucidated. Herein, Cu 2 O and CuSCN are coutilized to form an efficient and stable HTL. While uniform film formation using Cu 2 O is difficult despite its high mobility, a Cu 2 O− CuSCN nanocomposite can be excellently synthesized as an effective HTL, exhibiting a power conversion efficiency (PCE) of 19.2% and sustaining its PCE over 90% for 720 h under extreme conditions (85 °C/85% of relative humidity, encapsulated). A chemical distribution analysis by secondary-ion mass spectroscopy (SIMS) suggests that a Cu 2 O nanoparticle layer protects the interface between the perovskite and CuSCN. The optoelectronic properties of the nanocomposite HTL and the improved solar cell performance are correlated with the recombination rate, electronic trap distribution in the band gap, and charge extraction efficiencies.
Because of the facile formation of
defects in organometal halide perovskites, the defect passivation
has become an important prerequisite for the stable and efficient
perovskite solar cell (PSC). Regarding that ionic defects of the perovskites
play a significant role on the performance and stability of PSCs,
we introduce lithium fluorides as effective passivators based on their
strong ionic characteristics and small ionic radii. Both Li+ and F– are observed to successfully incorporate
within the perovskite layer, improving the device performances with
the best efficiency over 20%, while the hysteresis effects are significantly
reduced, confirming the passivation of perovskite defects. Moreover,
LiF restrains both thermal degradation and photodegradation of PSCs,
where over 90% of the initial efficiencies have been retained by LiF-incorporated
devices for more than 1000 h under either 1 sun illumination or 85
°C thermal condition. As the trap density of states is analyzed
before and after the thermal stress, not only the mitigation of electronic
traps as fabricated but also the dramatic relaxation of traps during
the postannealing step is observed with the LiF incorporation. From
this work, LiF has shown its potential as a promising ionic passivator,
and the phenomenal achievement of device stability by LiF provides
a clear insight to overcome the stability issues of PSCs, a key to
the commercialization of next-generation photovoltaics.
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