Regulating Surface Heterogeneity Maximizes Photovoltage and Operational Stability in Tin–Lead Perovskite Solar Cells

Gunasekaran, Rajendra Kumar; Jung, Jina; Yang, Sung Woong; Im, Doyun; Choi, Won Chang; Yun, Yeonghun; Lee, Sangwook

doi:10.1021/acsenergylett.3c02402

ACS Energy Lett.

2023

DOI: 10.1021/acsenergylett.3c02402

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Regulating Surface Heterogeneity Maximizes Photovoltage and Operational Stability in Tin–Lead Perovskite Solar Cells

Rajendra Kumar Gunasekaran,

Jina Jung,

Sung Woong Yang

et al.

Abstract: We present a surface reconstruction strategy for tin−lead perovskites, effectively addressing the issue of oxidized Sn fragments on surfaces and interfaces. Our surface treatment involving postfabrication iodide supplementation effectively regulates undesired surface binding states and reconstructs the compositional gradient. Through surfacesensitive and depth-resolved analysis, we unveil a strong correlation among surface compositional disorder, photovoltage, and operational stability in tin−lead perovskites.… Show more

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2024

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Cited by 11 publications

References 37 publications

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Understanding the Surface Chemistry of Tin Halide Perovskites

Treglia,

Prato,

et al. 2024

Adv Funct Materials

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The role of tin fluoride in defining the complex surface chemistry of tin halide perovskites (THP) is investigated. It is shown that oxygen is found on the surface of tin perovskite thin films even if prepared under a virtually inert environment; however, the presence of SnF2 strongly affects the chemical nature of the found species. Oxygen primarily binds to tin in the form of SnO2 only when SnF2 is added to the precursor solution, while it preferentially binds to carbon and hydrogen in pristine materials. Thanks to the spatial mapping of both the local chemical environment and photoluminescence, it is shown that pristine films have a higher accumulation of iodine at the grain boundaries while the addition of SnF2 allows for preserving the perovskite phase and reducing chemical and optical heterogeneities. Finally, SnF2 does not help in avoiding nor slowing down the degradation of the perovskite film when exposed to ambient air and oxidation occurs on the whole THP‐grain surface. These results provide insightful guidance toward understanding oxidation in THPs and elucidate its detrimental effect on the material's properties.

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Understanding the Surface Chemistry of Tin Halide Perovskites

Treglia,

Prato,

et al. 2024

Adv Funct Materials

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Ferromagnetic Nickel as a Sustainable Reducing Agent for Tin–Lead Mixed Perovskite in Single‐Junction and Tandem Solar Cells

Im,

Boonmongkolras,

Yun

et al. 2024

Advanced Science

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Narrow‐bandgap (NBG) Sn–Pb mixed perovskite solar cells (PSCs) represent a promising solution for surpassing the radiative efficiency of single‐junction solar cells. The unique bandgap tunability of halide perovskites enables optimal tandem configurations of wide‐bandgap (WBG) and NBG subcells. However, these devices are limited by the susceptibility of Sn2+ in the NBG bottom cell to being oxidized to Sn4+, creating detrimental Sn vacancies. Herein, a novel approach that replaces Sn particles with Ni particles is introduced as the reducing agent for Sn–Pb mixed perovskite precursor solutions. The ferromagnetic properties of Ni enable simple magnetic filtration, eliminating the filtration issues associated with Sn particles. Ni particles can be reused up to five times without significantly affecting the PSC's performance. Additionally, Ni effectively mitigates the oxidation of Sn2+ due to its low reduction potential (−0.23 V), thereby enhancing device performance. Single‐junction Sn–Pb mixed PSCs prepared using Ni achieve a power‐conversion efficiency (PCE) of 22.29%, retaining over 90% of their initial efficiency after 1250 h. Furthermore, Ni‐based all‐perovskite tandem solar cells combining 1.77 eV WBG top cells with 1.25 eV NBG bottom cells achieve a remarkable PCE of 28.13%. Thus, the proposed strategy can facilitate the commercialization of all‐perovskite tandem devices.

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Indium Iodide Additive Realizing Efficient Mixed Sn─Pb Perovskite Solar Cells

Liu,

Li,

Dong

et al. 2024

Advanced Energy Materials

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Low‐bandgap mixed tin (Sn)‐lead (Pb) perovskite solar cells promise efficiency beyond the pure‐Pb ones. However, the difference in the interaction rate of SnI2 and PbI2 with organic salts causes spatial distribution heterogeneity of Sn2+ and Pb2+ in mixed Sn─Pb perovskite layers. This causes a Sn‐rich surface, which can trigger more severe Sn2+ oxidation and nonradiative recombination. A strategy, of introducing indium ion (In3+) into the perovskite precursor solution to compete with Sn2+ when reacting with organic salts is developed. Therefore, the nucleation and crystallization of perovskite films are well‐controlled, leading to improved film quality with a more balanced Sn/Pb ratio on the film surface. Additionally, In3+ has a lower reduction potential compared to Sn2+ which can generate an extra energy barrier for Sn2+ oxidation. The improved film quality and reduced surface oxidation result in accelerated electron transfer and reduced carrier recombination rate. The modified devices achieve a power conversion efficiency (PCE) of 23.34%, representing one of the highest PCEs in mixed Sn─Pb solar cells made with PCBM.

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Regulating Surface Heterogeneity Maximizes Photovoltage and Operational Stability in Tin–Lead Perovskite Solar Cells

Cited by 11 publications

References 37 publications

Understanding the Surface Chemistry of Tin Halide Perovskites

Understanding the Surface Chemistry of Tin Halide Perovskites

Ferromagnetic Nickel as a Sustainable Reducing Agent for Tin–Lead Mixed Perovskite in Single‐Junction and Tandem Solar Cells

Indium Iodide Additive Realizing Efficient Mixed Sn─Pb Perovskite Solar Cells

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