Molecular Engineering of Alkylammonium Interfaces for Enhanced Efficiency in Perovskite Solar Cells

Ibtisam S. Almalki; Tarek I. Alanazi; Lujain Aldoghan; Noura Aldossari; Fatimh Almutawa; Rawan A. Alzahrani; Sultan M. Alenzi; Yahya A. Alzahrani; Ghazal S. Yafi; Abdulmajeed Almutairi; Abdurhman Aldukhail; Bader Alharthi; Abdulaziz Aljuwayr; Faisal S. Alghannam; Ali Z. Alanzi; Huda Alkhaldi; Fawziah Alhajri; Haitham S. Alhumud; Ali A. Alqarni; Mohammad Hayal Alotaibi; Nouf K. AL-Saleem; Masfer Alkahtani; Anwar Q. Alanazi; Masaud Almalki

doi:10.1002/solr.202500389

Molecular Engineering of Alkylammonium Interfaces for Enhanced Efficiency in Perovskite Solar Cells

Ibtisam S. Almalki
, Tarek I. Alanazi
, Lujain Aldoghan
, Noura Aldossari
, Fatimh Almutawa
, Rawan A. Alzahrani
, Sultan M. Alenzi
, Yahya A. Alzahrani
, Ghazal S. Yafi
, Abdulmajeed Almutairi
, Abdurhman Aldukhail
, Bader Alharthi
, Abdulaziz Aljuwayr
, Faisal S. Alghannam
, Ali Z. Alanzi
, Huda Alkhaldi
, Fawziah Alhajri
, Haitham S. Alhumud
, Ali A. Alqarni
, Mohammad Hayal Alotaibi

Nouf K. AL-Saleem^*, Masfer Alkahtani, Anwar Q. Alanazi^*, Masaud Almalki^*

^*Corresponding author for this work

Physics Department

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

Abstract

Power conversion efficiency (PCE) improvements in perovskite solar cells (PSCs) are increasingly constrained by nonradiative recombination at interfacial defects. In this study, we demonstrate a systematic interface engineering strategy using alkylammonium iodide salts with varying chain lengths from methylammonium (C1) to dodecylammonium (C12) to modulate the interface between the mixed-cation perovskite absorber (FAPbI₃)_0.97(MAPbBr₃)_0.03 and the hole-transport layer. Surface treatment with these salts significantly reduces interfacial recombination, as evidenced by enhanced photoluminescence and a strong chain-length-dependent increase in open-circuit voltage (V_OC) and fill factor (FF). Our champion device, passivated with dodecylammonium iodide, achieves a PCE of 24.6% with V_OC = 1.166 V and FF = 81.5%, marking a > 12% relative increase over the untreated control. Structural, optical, and electrical (J–V, SCAPS modeling) analyses collectively reveal that longer-chain cations form ultrathin 2D interfacial layers that suppress defect-mediated recombination without impeding charge transport. Additionally, these passivation layers impart enhanced stability under continuous illumination, ambient air exposure, and elevated temperature, with DDAI-treated devices maintaining over 88% of their initial performance after thermal aging at 65°C for 500 h. This work establishes alkylammonium chain length as a powerful tuning parameter for optimizing PSC interfaces and advancing high-efficiency, stable perovskite photovoltaics.

Original language	English
Article number	2500389
Journal	Solar RRL
Volume	9
Issue number	16
DOIs	https://doi.org/10.1002/solr.202500389
State	Published - Aug 2025

Keywords

alkylammonium iodide passivation
interface engineering
perovskite solar cells
quasi-Fermi level splitting
SCAPS simulation

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/solr.202500389

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Almalki, I. S., Alanazi, T. I., Aldoghan, L., Aldossari, N., Almutawa, F., Alzahrani, R. A., Alenzi, S. M., Alzahrani, Y. A., Yafi, G. S., Almutairi, A., Aldukhail, A., Alharthi, B., Aljuwayr, A., Alghannam, F. S., Alanzi, A. Z., Alkhaldi, H., Alhajri, F., Alhumud, H. S., Alqarni, A. A., ... Almalki, M. (2025). Molecular Engineering of Alkylammonium Interfaces for Enhanced Efficiency in Perovskite Solar Cells. Solar RRL, 9(16), Article 2500389. https://doi.org/10.1002/solr.202500389

@article{d2c335db254f43c6951fbb1363b21bc8,

title = "Molecular Engineering of Alkylammonium Interfaces for Enhanced Efficiency in Perovskite Solar Cells",

abstract = "Power conversion efficiency (PCE) improvements in perovskite solar cells (PSCs) are increasingly constrained by nonradiative recombination at interfacial defects. In this study, we demonstrate a systematic interface engineering strategy using alkylammonium iodide salts with varying chain lengths from methylammonium (C1) to dodecylammonium (C12) to modulate the interface between the mixed-cation perovskite absorber (FAPbI3)0.97(MAPbBr3)0.03 and the hole-transport layer. Surface treatment with these salts significantly reduces interfacial recombination, as evidenced by enhanced photoluminescence and a strong chain-length-dependent increase in open-circuit voltage (VOC) and fill factor (FF). Our champion device, passivated with dodecylammonium iodide, achieves a PCE of 24.6\% with VOC = 1.166 V and FF = 81.5\%, marking a > 12\% relative increase over the untreated control. Structural, optical, and electrical (J–V, SCAPS modeling) analyses collectively reveal that longer-chain cations form ultrathin 2D interfacial layers that suppress defect-mediated recombination without impeding charge transport. Additionally, these passivation layers impart enhanced stability under continuous illumination, ambient air exposure, and elevated temperature, with DDAI-treated devices maintaining over 88\% of their initial performance after thermal aging at 65°C for 500 h. This work establishes alkylammonium chain length as a powerful tuning parameter for optimizing PSC interfaces and advancing high-efficiency, stable perovskite photovoltaics.",

keywords = "alkylammonium iodide passivation, interface engineering, perovskite solar cells, quasi-Fermi level splitting, SCAPS simulation",

author = "Almalki, \{Ibtisam S.\} and Alanazi, \{Tarek I.\} and Lujain Aldoghan and Noura Aldossari and Fatimh Almutawa and Alzahrani, \{Rawan A.\} and Alenzi, \{Sultan M.\} and Alzahrani, \{Yahya A.\} and Yafi, \{Ghazal S.\} and Abdulmajeed Almutairi and Abdurhman Aldukhail and Bader Alharthi and Abdulaziz Aljuwayr and Alghannam, \{Faisal S.\} and Alanzi, \{Ali Z.\} and Huda Alkhaldi and Fawziah Alhajri and Alhumud, \{Haitham S.\} and Alqarni, \{Ali A.\} and Alotaibi, \{Mohammad Hayal\} and AL-Saleem, \{Nouf K.\} and Masfer Alkahtani and Alanazi, \{Anwar Q.\} and Masaud Almalki",

note = "Publisher Copyright: {\textcopyright} 2025 Wiley-VCH GmbH.",

year = "2025",

month = aug,

doi = "10.1002/solr.202500389",

language = "English",

volume = "9",

journal = "Solar RRL",

issn = "2367-198X",

number = "16",

}

Almalki, IS, Alanazi, TI, Aldoghan, L, Aldossari, N, Almutawa, F, Alzahrani, RA, Alenzi, SM, Alzahrani, YA, Yafi, GS, Almutairi, A, Aldukhail, A, Alharthi, B, Aljuwayr, A, Alghannam, FS, Alanzi, AZ, Alkhaldi, H , Alhajri, F, Alhumud, HS, Alqarni, AA, Alotaibi, MH, AL-Saleem, NK, Alkahtani, M, Alanazi, AQ & Almalki, M 2025, 'Molecular Engineering of Alkylammonium Interfaces for Enhanced Efficiency in Perovskite Solar Cells', Solar RRL, vol. 9, no. 16, 2500389. https://doi.org/10.1002/solr.202500389

TY - JOUR

T1 - Molecular Engineering of Alkylammonium Interfaces for Enhanced Efficiency in Perovskite Solar Cells

AU - Almalki, Ibtisam S.

AU - Alanazi, Tarek I.

AU - Aldoghan, Lujain

AU - Aldossari, Noura

AU - Almutawa, Fatimh

AU - Alzahrani, Rawan A.

AU - Alenzi, Sultan M.

AU - Alzahrani, Yahya A.

AU - Yafi, Ghazal S.

AU - Almutairi, Abdulmajeed

AU - Aldukhail, Abdurhman

AU - Alharthi, Bader

AU - Aljuwayr, Abdulaziz

AU - Alghannam, Faisal S.

AU - Alanzi, Ali Z.

AU - Alkhaldi, Huda

AU - Alhajri, Fawziah

AU - Alhumud, Haitham S.

AU - Alqarni, Ali A.

AU - Alotaibi, Mohammad Hayal

AU - AL-Saleem, Nouf K.

AU - Alkahtani, Masfer

AU - Alanazi, Anwar Q.

AU - Almalki, Masaud

PY - 2025/8

Y1 - 2025/8

N2 - Power conversion efficiency (PCE) improvements in perovskite solar cells (PSCs) are increasingly constrained by nonradiative recombination at interfacial defects. In this study, we demonstrate a systematic interface engineering strategy using alkylammonium iodide salts with varying chain lengths from methylammonium (C1) to dodecylammonium (C12) to modulate the interface between the mixed-cation perovskite absorber (FAPbI3)0.97(MAPbBr3)0.03 and the hole-transport layer. Surface treatment with these salts significantly reduces interfacial recombination, as evidenced by enhanced photoluminescence and a strong chain-length-dependent increase in open-circuit voltage (VOC) and fill factor (FF). Our champion device, passivated with dodecylammonium iodide, achieves a PCE of 24.6% with VOC = 1.166 V and FF = 81.5%, marking a > 12% relative increase over the untreated control. Structural, optical, and electrical (J–V, SCAPS modeling) analyses collectively reveal that longer-chain cations form ultrathin 2D interfacial layers that suppress defect-mediated recombination without impeding charge transport. Additionally, these passivation layers impart enhanced stability under continuous illumination, ambient air exposure, and elevated temperature, with DDAI-treated devices maintaining over 88% of their initial performance after thermal aging at 65°C for 500 h. This work establishes alkylammonium chain length as a powerful tuning parameter for optimizing PSC interfaces and advancing high-efficiency, stable perovskite photovoltaics.

AB - Power conversion efficiency (PCE) improvements in perovskite solar cells (PSCs) are increasingly constrained by nonradiative recombination at interfacial defects. In this study, we demonstrate a systematic interface engineering strategy using alkylammonium iodide salts with varying chain lengths from methylammonium (C1) to dodecylammonium (C12) to modulate the interface between the mixed-cation perovskite absorber (FAPbI3)0.97(MAPbBr3)0.03 and the hole-transport layer. Surface treatment with these salts significantly reduces interfacial recombination, as evidenced by enhanced photoluminescence and a strong chain-length-dependent increase in open-circuit voltage (VOC) and fill factor (FF). Our champion device, passivated with dodecylammonium iodide, achieves a PCE of 24.6% with VOC = 1.166 V and FF = 81.5%, marking a > 12% relative increase over the untreated control. Structural, optical, and electrical (J–V, SCAPS modeling) analyses collectively reveal that longer-chain cations form ultrathin 2D interfacial layers that suppress defect-mediated recombination without impeding charge transport. Additionally, these passivation layers impart enhanced stability under continuous illumination, ambient air exposure, and elevated temperature, with DDAI-treated devices maintaining over 88% of their initial performance after thermal aging at 65°C for 500 h. This work establishes alkylammonium chain length as a powerful tuning parameter for optimizing PSC interfaces and advancing high-efficiency, stable perovskite photovoltaics.

KW - alkylammonium iodide passivation

KW - interface engineering

KW - perovskite solar cells

KW - quasi-Fermi level splitting

KW - SCAPS simulation

UR - https://www.scopus.com/pages/publications/105010629334

U2 - 10.1002/solr.202500389

DO - 10.1002/solr.202500389

M3 - Article

AN - SCOPUS:105010629334

SN - 2367-198X

VL - 9

JO - Solar RRL

JF - Solar RRL

IS - 16

M1 - 2500389

ER -

Molecular Engineering of Alkylammonium Interfaces for Enhanced Efficiency in Perovskite Solar Cells

Abstract

Keywords

UN SDGs

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