A latest research printed in Small highlights how incorporating the metal-organic framework (MOF) UiO-66 can considerably improve each the effectivity and stability of tin halide perovskite photo voltaic cells (TPSCs). Researchers element the structural and chemical advantages of UiO-66 that contribute to those enhancements.
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Background
MOFs are porous supplies made up of steel ions related by natural molecules. Their giant floor space, adjustable pore sizes, and chemical versatility make them helpful for enhancing photo voltaic cells. These properties assist MOFs work together with perovskite supplies, doubtlessly resulting in smoother movies with fewer defects.
Tin halide perovskites are an interesting various to lead-based photo voltaic cells attributable to their excellent bandgap and excessive charge-carrier mobility. Nevertheless, their sensible use is hindered by poor crystal high quality and fast degradation when uncovered to air.
Formamidinium tin iodide (FASnI3) is a very promising tin-based perovskite, nevertheless it stays unstable underneath environmental stress. To deal with this, researchers investigated UiO-66, a zirconium-carboxylate MOF identified for its stability towards moisture and chemical compounds, as a manner to enhance the efficiency and sturdiness of TPSCs.
The Research
On this analysis, UiO-66 was synthesized with smaller grain sizes (diminished from 200–300 nm to 30–50 nm) to higher combine into the perovskite movie. X-ray diffraction confirmed that the MOF maintained its excessive crystallinity and purity.
UiO-66 was included into FASnI3 utilizing a one-step spin-coating technique on a gap transport layer made from PEDOT:PSS. The movies had been then annealed at 100 °C to finish crystallization. The complete course of was carried out in a nitrogen-filled glovebox to take care of managed circumstances.
To evaluate the machine efficiency, researchers performed current-voltage (J-V) measurements underneath customary AM 1.5 daylight circumstances, in addition to stability exams to guage how lengthy the units maintained effectivity underneath ambient publicity.
Outcomes and Dialogue
The addition of UiO-66 led to a noticeable enhance in energy conversion effectivity (PCE), from 11.43 % to 12.64 %. Researchers attributed this enchancment to the MOF’s capability to control the crystallization of FASnI3, resulting in higher-quality movies and higher digital properties.
Scanning electron microscopy (SEM) revealed that the UiO-66-enhanced movies had been denser and extra uniform. Optical evaluation utilizing UV-vis spectroscopy confirmed that mild absorption was improved, whereas time-resolved photoluminescence (TRPL) measurements indicated that service lifetimes had been prolonged, suggesting a discount in non-radiative recombination losses. These outcomes verify that UiO-66 performs a key position in optimizing the structural and optical properties of the perovskite movie.
Stability exams confirmed that TPSCs with UiO-66 maintained over 90 % of their preliminary effectivity after 100 days in a nitrogen glovebox. In distinction, units with out UiO-66 misplaced important effectivity, retaining solely 38 % of their preliminary efficiency after 144 hours. The improved stability was linked to UiO-66’s capability to scale back defect density and its sturdy interactions with Sn2+ ions, which helped reinforce the perovskite construction.
Moreover, the porous construction of UiO-66 acted as a protecting layer towards moisture and oxygen, additional extending the lifespan of the photo voltaic cells. Theoretical calculations and density purposeful concept (DFT) simulations confirmed sturdy interactions between the MOF’s carboxylate teams and tin ions, providing additional stability on the molecular stage.
Conclusion
This research demonstrates that integrating UiO-66 into tin halide perovskite photo voltaic cells considerably enhances effectivity and stability. The incorporation of UiO-66 facilitates improved crystallization kinetics, defect passivation, and superior cost transport properties, leading to greater energy conversion effectivity and prolonged operational stability.
These findings reinforce the position of MOFs as a viable technique for addressing the persistent challenges of tin-based perovskites. By optimizing each structural and digital properties, UiO-66 integration brings TPSCs nearer to sensible utility, providing a promising pathway for advancing lead-free photovoltaic applied sciences.
Journal Reference
Yin Y., et al. (2025). Enhanced Effectivity and Stability of Tin Halide Perovskite Photo voltaic Cells Via MOF Integration. Small. DOI: 10.1002/smll.202411346, https://onlinelibrary.wiley.com/doi/10.1002/smll.202411346