Impact of Halogen Groups on the Properties of PEA-Based 2D Pb–Sn Halide Perovskites

Elham Foadian; Sheryl L. Sanchez; Sumner B. Harris; Benjamin J. Lawrie; Astita Dubey; Yipeng Tang; Bin Hu; Jonghee Yang; Mahshid Ahmadi

doi:10.1002/adom.202403120

Impact of Halogen Groups on the Properties of PEA-Based 2D Pb–Sn Halide Perovskites

Elham Foadian, Sheryl L. Sanchez, Sumner B. Harris, Benjamin J. Lawrie, Astita Dubey, Yipeng Tang, Bin Hu, Jonghee Yang, Mahshid Ahmadi

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Abstract

Tuning broad emission in 2D Pb–Sn halide perovskites (HPs) is essential for advancing optoelectronic applications, particularly for color-tunable and white-light-emitting devices. This broad emission is linked to structural factors, such as defects and phase segregation of the Pb component within the Pb–Sn system, which are strongly influenced by the molecular structure and chemical properties of spacer cations. Atomic tuning of the spacers via halogenation opens up a new way to fine-tune the molecular properties, enabling further augmentations of HP functionalities. Nevertheless, the distinct broad emission's sensitivity to spacer chemistry remains underexplored. Here, halogenation's influence is systematically investigated on 2D HP emission characteristics using a high-throughput workflow. These findings reveal that the F-containing phenethylammonium (4F-PEA) spacer narrows the broadband PL, whereas Cl broadens it. Through a correlative study, it is found that 4F-PEA reduces not only the local phase segregation but also the defect levels and microstrains in 2D HPs. This is likely attributed to the manifestation of less lattice distortion via stronger surface coordination of the dipole-augmented 4F-PEA. These results highlight halogenation as a key factor in modulating phase segregation and defect density in 2D Pb–Sn HPs, offering a promising pathway to tune the emission for enhanced optoelectronic performance.

Original language	English
Article number	2403120
Journal	Advanced Optical Materials
Volume	13
Issue number	11
DOIs	https://doi.org/10.1002/adom.202403120
State	Published - Apr 14 2025

Funding

E.F. and M.A. acknowledge support from the National Science Foundation (NSF), Award Number 2043205, and Alfred P. Sloan Foundation, award No. FG-2022-18275. S.S. acknowledges partial support from the Center for Materials Processing (CMP) at the University of Tennessee, Knoxville. A.D. is grateful to German Academic Exchange Service (DeutscherAkademischer Austauschdienst: DAAD-PRIME 2023-24) postdoctoral researchers international mobility experience funding program. The XPS and CL experiments were supported by the Center for Nanophase Materials Sciences (CNMS), which is a US Department of Energy, Office of Science User Facility at Oak Ridge National Laboratory. E.F. and M.A. acknowledge support from the National Science Foundation (NSF), Award Number 2043205, and Alfred P. Sloan Foundation, award No. FG‐2022‐18275. S.S. acknowledges partial support from the Center for Materials Processing (CMP) at the University of Tennessee, Knoxville. A.D. is grateful to German Academic Exchange Service (DeutscherAkademischer Austauschdienst: DAAD‐PRIME 2023‐24) postdoctoral researchers international mobility experience funding program. The XPS and CL experiments were supported by the Center for Nanophase Materials Sciences (CNMS), which is a US Department of Energy, Office of Science User Facility at Oak Ridge National Laboratory.

Keywords

2D Pb–Sn halide perovskites
defects
halogenation of spacer cation
high-throughput experiments
phase segregation

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abstract = "Tuning broad emission in 2D Pb–Sn halide perovskites (HPs) is essential for advancing optoelectronic applications, particularly for color-tunable and white-light-emitting devices. This broad emission is linked to structural factors, such as defects and phase segregation of the Pb component within the Pb–Sn system, which are strongly influenced by the molecular structure and chemical properties of spacer cations. Atomic tuning of the spacers via halogenation opens up a new way to fine-tune the molecular properties, enabling further augmentations of HP functionalities. Nevertheless, the distinct broad emission's sensitivity to spacer chemistry remains underexplored. Here, halogenation's influence is systematically investigated on 2D HP emission characteristics using a high-throughput workflow. These findings reveal that the F-containing phenethylammonium (4F-PEA) spacer narrows the broadband PL, whereas Cl broadens it. Through a correlative study, it is found that 4F-PEA reduces not only the local phase segregation but also the defect levels and microstrains in 2D HPs. This is likely attributed to the manifestation of less lattice distortion via stronger surface coordination of the dipole-augmented 4F-PEA. These results highlight halogenation as a key factor in modulating phase segregation and defect density in 2D Pb–Sn HPs, offering a promising pathway to tune the emission for enhanced optoelectronic performance.",

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AU - Dubey, Astita

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AB - Tuning broad emission in 2D Pb–Sn halide perovskites (HPs) is essential for advancing optoelectronic applications, particularly for color-tunable and white-light-emitting devices. This broad emission is linked to structural factors, such as defects and phase segregation of the Pb component within the Pb–Sn system, which are strongly influenced by the molecular structure and chemical properties of spacer cations. Atomic tuning of the spacers via halogenation opens up a new way to fine-tune the molecular properties, enabling further augmentations of HP functionalities. Nevertheless, the distinct broad emission's sensitivity to spacer chemistry remains underexplored. Here, halogenation's influence is systematically investigated on 2D HP emission characteristics using a high-throughput workflow. These findings reveal that the F-containing phenethylammonium (4F-PEA) spacer narrows the broadband PL, whereas Cl broadens it. Through a correlative study, it is found that 4F-PEA reduces not only the local phase segregation but also the defect levels and microstrains in 2D HPs. This is likely attributed to the manifestation of less lattice distortion via stronger surface coordination of the dipole-augmented 4F-PEA. These results highlight halogenation as a key factor in modulating phase segregation and defect density in 2D Pb–Sn HPs, offering a promising pathway to tune the emission for enhanced optoelectronic performance.

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Impact of Halogen Groups on the Properties of PEA-Based 2D Pb–Sn Halide Perovskites

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