Refining Multiscale Heterogeneity in Perovskite Solar Cells via Interfacial Chemistry Homogenization

Hochan Song; Jiyeon Won; Hak Beom Kim; Eunseo Lee; Jaehwi Lee; Dongryeol Lee; Subeom Shin; Sein Chung; Kilwon Cho; Jaewon Lee; Bo Ram Lee; Myoung Hoon Song; Dong Suk Kim; Jin Young Kim; Dong Won Kang; Jonghee Yang; Sang Min Lee; Hyosung Choi

doi:10.1002/adfm.202421402

Refining Multiscale Heterogeneity in Perovskite Solar Cells via Interfacial Chemistry Homogenization

Hochan Song, Jiyeon Won, Hak Beom Kim, Eunseo Lee, Jaehwi Lee, Dongryeol Lee, Subeom Shin, Sein Chung, Kilwon Cho, Jaewon Lee, Bo Ram Lee, Myoung Hoon Song, Dong Suk Kim, Jin Young Kim, Dong Won Kang, Jonghee Yang, Sang Min Lee, Hyosung Choi

Research output: Contribution to journal › Article › peer-review

Abstract

Controlling multiscale structural heterogeneities in halide perovskites (HPs) is a key bottleneck to achieving the reproducible high-performances and longevity of perovskite solar cells (PSCs). A correlative understanding of structural and chemical features at the HP/charge transport layer interface is vital to realizing homogeneous and monolithic crystal matrices. Yet, this is not fully resolved as it requires holistic investigations of the multilayer systems. Herein, the intricate correlations of the interfacial features are resolved by utilizing chemically modified colloidal SnO₂ nanoparticles (NPs) with ethylenediaminetetraacetic acid-grafted polymeric chitosan (C-EDTA). This chemical approach drastically enhances colloidal stability of the NPs, thereby manifesting a chemically homogenized surface of the electron transport layer. This promotes a homogeneous crystallization, refining the HP matrix while suppressing the evolution of pinholes and grain boundary grooves at the buried interface. This chemically and structurally refined heterointerface system significantly minimizes the interfacial charge recombination, thereby realizing improved performances of the PSCs with the highest power conversion efficiency of 25.12%. This work provides key insights into the role of structural refinement at the interface benefiting the performances and durability of PSCs − a vital principle in realizing sustainable solar energy platforms.

Original language	English
Journal	Advanced Functional Materials
DOIs	https://doi.org/10.1002/adfm.202421402
Publication status	Accepted/In press - 2025

Bibliographical note

Publisher Copyright:
© 2025 Wiley-VCH GmbH.

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
General Chemistry
Biomaterials
General Materials Science
Condensed Matter Physics
Electrochemistry

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10.1002/adfm.202421402

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Song, H., Won, J., Kim, H. B., Lee, E., Lee, J., Lee, D., Shin, S., Chung, S., Cho, K., Lee, J., Lee, B. R., Song, M. H., Kim, D. S., Kim, J. Y., Kang, D. W., Yang, J., Lee, S. M., & Choi, H. (Accepted/In press). Refining Multiscale Heterogeneity in Perovskite Solar Cells via Interfacial Chemistry Homogenization. Advanced Functional Materials. https://doi.org/10.1002/adfm.202421402

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title = "Refining Multiscale Heterogeneity in Perovskite Solar Cells via Interfacial Chemistry Homogenization",

abstract = "Controlling multiscale structural heterogeneities in halide perovskites (HPs) is a key bottleneck to achieving the reproducible high-performances and longevity of perovskite solar cells (PSCs). A correlative understanding of structural and chemical features at the HP/charge transport layer interface is vital to realizing homogeneous and monolithic crystal matrices. Yet, this is not fully resolved as it requires holistic investigations of the multilayer systems. Herein, the intricate correlations of the interfacial features are resolved by utilizing chemically modified colloidal SnO2 nanoparticles (NPs) with ethylenediaminetetraacetic acid-grafted polymeric chitosan (C-EDTA). This chemical approach drastically enhances colloidal stability of the NPs, thereby manifesting a chemically homogenized surface of the electron transport layer. This promotes a homogeneous crystallization, refining the HP matrix while suppressing the evolution of pinholes and grain boundary grooves at the buried interface. This chemically and structurally refined heterointerface system significantly minimizes the interfacial charge recombination, thereby realizing improved performances of the PSCs with the highest power conversion efficiency of 25.12%. This work provides key insights into the role of structural refinement at the interface benefiting the performances and durability of PSCs − a vital principle in realizing sustainable solar energy platforms.",

keywords = "SnO nanoparticles, heterointerfaces, multiscale heterogeneities, perovskite solar cell, surface chemistry",

author = "Hochan Song and Jiyeon Won and Kim, {Hak Beom} and Eunseo Lee and Jaehwi Lee and Dongryeol Lee and Subeom Shin and Sein Chung and Kilwon Cho and Jaewon Lee and Lee, {Bo Ram} and Song, {Myoung Hoon} and Kim, {Dong Suk} and Kim, {Jin Young} and Kang, {Dong Won} and Jonghee Yang and Lee, {Sang Min} and Hyosung Choi",

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year = "2025",

doi = "10.1002/adfm.202421402",

language = "English",

journal = "Advanced Functional Materials",

issn = "1616-301X",

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T1 - Refining Multiscale Heterogeneity in Perovskite Solar Cells via Interfacial Chemistry Homogenization

AU - Song, Hochan

AU - Won, Jiyeon

AU - Kim, Hak Beom

AU - Lee, Eunseo

AU - Lee, Jaehwi

AU - Lee, Dongryeol

AU - Shin, Subeom

AU - Chung, Sein

AU - Cho, Kilwon

AU - Lee, Jaewon

AU - Lee, Bo Ram

AU - Song, Myoung Hoon

AU - Kim, Dong Suk

AU - Kim, Jin Young

AU - Kang, Dong Won

AU - Yang, Jonghee

AU - Lee, Sang Min

AU - Choi, Hyosung

PY - 2025

Y1 - 2025

N2 - Controlling multiscale structural heterogeneities in halide perovskites (HPs) is a key bottleneck to achieving the reproducible high-performances and longevity of perovskite solar cells (PSCs). A correlative understanding of structural and chemical features at the HP/charge transport layer interface is vital to realizing homogeneous and monolithic crystal matrices. Yet, this is not fully resolved as it requires holistic investigations of the multilayer systems. Herein, the intricate correlations of the interfacial features are resolved by utilizing chemically modified colloidal SnO2 nanoparticles (NPs) with ethylenediaminetetraacetic acid-grafted polymeric chitosan (C-EDTA). This chemical approach drastically enhances colloidal stability of the NPs, thereby manifesting a chemically homogenized surface of the electron transport layer. This promotes a homogeneous crystallization, refining the HP matrix while suppressing the evolution of pinholes and grain boundary grooves at the buried interface. This chemically and structurally refined heterointerface system significantly minimizes the interfacial charge recombination, thereby realizing improved performances of the PSCs with the highest power conversion efficiency of 25.12%. This work provides key insights into the role of structural refinement at the interface benefiting the performances and durability of PSCs − a vital principle in realizing sustainable solar energy platforms.

AB - Controlling multiscale structural heterogeneities in halide perovskites (HPs) is a key bottleneck to achieving the reproducible high-performances and longevity of perovskite solar cells (PSCs). A correlative understanding of structural and chemical features at the HP/charge transport layer interface is vital to realizing homogeneous and monolithic crystal matrices. Yet, this is not fully resolved as it requires holistic investigations of the multilayer systems. Herein, the intricate correlations of the interfacial features are resolved by utilizing chemically modified colloidal SnO2 nanoparticles (NPs) with ethylenediaminetetraacetic acid-grafted polymeric chitosan (C-EDTA). This chemical approach drastically enhances colloidal stability of the NPs, thereby manifesting a chemically homogenized surface of the electron transport layer. This promotes a homogeneous crystallization, refining the HP matrix while suppressing the evolution of pinholes and grain boundary grooves at the buried interface. This chemically and structurally refined heterointerface system significantly minimizes the interfacial charge recombination, thereby realizing improved performances of the PSCs with the highest power conversion efficiency of 25.12%. This work provides key insights into the role of structural refinement at the interface benefiting the performances and durability of PSCs − a vital principle in realizing sustainable solar energy platforms.

KW - SnO nanoparticles

KW - heterointerfaces

KW - multiscale heterogeneities

KW - perovskite solar cell

KW - surface chemistry

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JO - Advanced Functional Materials

JF - Advanced Functional Materials

ER -

Refining Multiscale Heterogeneity in Perovskite Solar Cells via Interfacial Chemistry Homogenization

Abstract

Bibliographical note

All Science Journal Classification (ASJC) codes

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