Volatile additive for selective tuning of non-fullerene acceptor morphology in the active layer of organic solar cells

Standard

Volatile additive for selective tuning of non-fullerene acceptor morphology in the active layer of organic solar cells. / Baranov, Denis S.; Molchanov, Ivan A.; Kravets, Natalia V. и др.

в: Organic Electronics: physics, materials, applications, Том 144, 107283, 09.2025.

Результаты исследований: Научные публикации в периодических изданиях › статья › Рецензирование

Harvard

Baranov, DS, Molchanov, IA, Kravets, NV, Kobeleva, ES, Uvarov, MN, Sandzhieva, MA, Aleshin, DK, Makarov, SV, Jiang, X, Zhang, Y, Zinov'ev, VA, Gatilov, YV, Sukhikh, AS, Kurtsevich, AE, Degtyarenko, KM & Kulik, LV 2025, 'Volatile additive for selective tuning of non-fullerene acceptor morphology in the active layer of organic solar cells', Organic Electronics: physics, materials, applications, Том. 144, 107283. https://doi.org/10.1016/j.orgel.2025.107283

APA

Baranov, D. S., Molchanov, I. A., Kravets, N. V., Kobeleva, E. S., Uvarov, M. N., Sandzhieva, M. A., Aleshin, D. K., Makarov, S. V., Jiang, X., Zhang, Y., Zinov'ev, V. A., Gatilov, Y. V., Sukhikh, A. S., Kurtsevich, A. E., Degtyarenko, K. M., & Kulik, L. V. (2025). Volatile additive for selective tuning of non-fullerene acceptor morphology in the active layer of organic solar cells. Organic Electronics: physics, materials, applications, 144, [107283]. https://doi.org/10.1016/j.orgel.2025.107283

Vancouver

Baranov DS, Molchanov IA, Kravets NV, Kobeleva ES, Uvarov MN, Sandzhieva MA и др. Volatile additive for selective tuning of non-fullerene acceptor morphology in the active layer of organic solar cells. Organic Electronics: physics, materials, applications. 2025 сент.;144:107283. doi: 10.1016/j.orgel.2025.107283

Author

Baranov, Denis S. ; Molchanov, Ivan A. ; Kravets, Natalia V. и др. / Volatile additive for selective tuning of non-fullerene acceptor morphology in the active layer of organic solar cells. в: Organic Electronics: physics, materials, applications. 2025 ; Том 144.

BibTeX

@article{a12f0b9f45074a3c9498fadf4daee1c7,

title = "Volatile additive for selective tuning of non-fullerene acceptor morphology in the active layer of organic solar cells",

abstract = "2-(2-Methylphenyl)benzo[b]thiophene (MPBT) is synthesized and applied as volatile additive to PM6/Y6 active layer of organic solar cells, where PM6 is donor polymer, Y6 is non-fullerene acceptor. Contrary to usual solvent additives, MPBT is not removed from the active layer during spin-coating. However, due to volatility of MPBT, annealing at 120 °C allows for its complete removal from PM6/Y6 composite. Moreover, its morphology is markedly altered by MPBT, as it is evidenced by optical spectroscopy and atomic force microscopy. For a thin PM6/Y6 active layer (about 70 nm) cast from chlorobenzene, the optimal concentration of MPBT is 5 wt %, relative to the solvent. Use of this additive leads to improvement of short circuit current JSC and fill factor (FF), and consequently, to power conversion efficiency (PCE) increase. External quantum efficiency (EQE) is improved within the whole range of PM6:Y6 optical absorption (350–850 nm). Optical, X-ray diffraction, and atomic-force microscopy data confirm ordering of Y6 domains during MPBT volatilization, while morphology of PM6 domains is almost not altered. Space-charge limited current measurement evidences that electron mobility increases several times upon volatilization of MPBT from PM6:Y6 film, while hole mobility remains essentially unchanged. Surface free energy measurement confirms preferential miscibility of MPBT with Y6 component of the active layer rather than with PM6 component. Storage and operational stability of the solar cells processed with MPBT markedly increase. GIWAXS pattern of pristine Y6 film processed with MPBT show unusually high orientation ordering of Y6 crystallines with respect to the substrate. The novel approach based on intermediate donor:acceptor:additive ternary blend gives additional degree of control of active layer properties by selective tuning of the acceptor morphology.",

keywords = "Bulk heterojunction, Charge mobility, Degradation, Non-fullerene acceptor, Semiconducting polymer, Volatile additive",

author = "Baranov, {Denis S.} and Molchanov, {Ivan A.} and Kravets, {Natalia V.} and Kobeleva, {Elena S.} and Uvarov, {Mikhail N.} and Sandzhieva, {Maria A.} and Aleshin, {Danil K.} and Makarov, {Sergey V.} and Xingjian Jiang and Yong Zhang and Zinov'ev, {Vladimir A.} and Gatilov, {Yuri V.} and Sukhikh, {Aleksandr S.} and Kurtsevich, {Alexander E.} and Degtyarenko, {Konstantin M.} and Kulik, {Leonid V.}",

year = "2025",

month = sep,

doi = "10.1016/j.orgel.2025.107283",

language = "English",

volume = "144",

journal = "Organic Electronics: physics, materials, applications",

issn = "1566-1199",

publisher = "Elsevier Science Publishing Company, Inc.",

}

RIS

TY - JOUR

T1 - Volatile additive for selective tuning of non-fullerene acceptor morphology in the active layer of organic solar cells

AU - Baranov, Denis S.

AU - Molchanov, Ivan A.

AU - Kravets, Natalia V.

AU - Kobeleva, Elena S.

AU - Uvarov, Mikhail N.

AU - Sandzhieva, Maria A.

AU - Aleshin, Danil K.

AU - Makarov, Sergey V.

AU - Jiang, Xingjian

AU - Zhang, Yong

AU - Zinov'ev, Vladimir A.

AU - Gatilov, Yuri V.

AU - Sukhikh, Aleksandr S.

AU - Kurtsevich, Alexander E.

AU - Degtyarenko, Konstantin M.

AU - Kulik, Leonid V.

PY - 2025/9

Y1 - 2025/9

N2 - 2-(2-Methylphenyl)benzo[b]thiophene (MPBT) is synthesized and applied as volatile additive to PM6/Y6 active layer of organic solar cells, where PM6 is donor polymer, Y6 is non-fullerene acceptor. Contrary to usual solvent additives, MPBT is not removed from the active layer during spin-coating. However, due to volatility of MPBT, annealing at 120 °C allows for its complete removal from PM6/Y6 composite. Moreover, its morphology is markedly altered by MPBT, as it is evidenced by optical spectroscopy and atomic force microscopy. For a thin PM6/Y6 active layer (about 70 nm) cast from chlorobenzene, the optimal concentration of MPBT is 5 wt %, relative to the solvent. Use of this additive leads to improvement of short circuit current JSC and fill factor (FF), and consequently, to power conversion efficiency (PCE) increase. External quantum efficiency (EQE) is improved within the whole range of PM6:Y6 optical absorption (350–850 nm). Optical, X-ray diffraction, and atomic-force microscopy data confirm ordering of Y6 domains during MPBT volatilization, while morphology of PM6 domains is almost not altered. Space-charge limited current measurement evidences that electron mobility increases several times upon volatilization of MPBT from PM6:Y6 film, while hole mobility remains essentially unchanged. Surface free energy measurement confirms preferential miscibility of MPBT with Y6 component of the active layer rather than with PM6 component. Storage and operational stability of the solar cells processed with MPBT markedly increase. GIWAXS pattern of pristine Y6 film processed with MPBT show unusually high orientation ordering of Y6 crystallines with respect to the substrate. The novel approach based on intermediate donor:acceptor:additive ternary blend gives additional degree of control of active layer properties by selective tuning of the acceptor morphology.

AB - 2-(2-Methylphenyl)benzo[b]thiophene (MPBT) is synthesized and applied as volatile additive to PM6/Y6 active layer of organic solar cells, where PM6 is donor polymer, Y6 is non-fullerene acceptor. Contrary to usual solvent additives, MPBT is not removed from the active layer during spin-coating. However, due to volatility of MPBT, annealing at 120 °C allows for its complete removal from PM6/Y6 composite. Moreover, its morphology is markedly altered by MPBT, as it is evidenced by optical spectroscopy and atomic force microscopy. For a thin PM6/Y6 active layer (about 70 nm) cast from chlorobenzene, the optimal concentration of MPBT is 5 wt %, relative to the solvent. Use of this additive leads to improvement of short circuit current JSC and fill factor (FF), and consequently, to power conversion efficiency (PCE) increase. External quantum efficiency (EQE) is improved within the whole range of PM6:Y6 optical absorption (350–850 nm). Optical, X-ray diffraction, and atomic-force microscopy data confirm ordering of Y6 domains during MPBT volatilization, while morphology of PM6 domains is almost not altered. Space-charge limited current measurement evidences that electron mobility increases several times upon volatilization of MPBT from PM6:Y6 film, while hole mobility remains essentially unchanged. Surface free energy measurement confirms preferential miscibility of MPBT with Y6 component of the active layer rather than with PM6 component. Storage and operational stability of the solar cells processed with MPBT markedly increase. GIWAXS pattern of pristine Y6 film processed with MPBT show unusually high orientation ordering of Y6 crystallines with respect to the substrate. The novel approach based on intermediate donor:acceptor:additive ternary blend gives additional degree of control of active layer properties by selective tuning of the acceptor morphology.

KW - Bulk heterojunction

KW - Charge mobility

KW - Degradation

KW - Non-fullerene acceptor

KW - Semiconducting polymer

KW - Volatile additive

UR - https://www.mendeley.com/catalogue/dc97fff2-7559-38c7-9e32-79b3b0dfccf2/

UR - https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=105007297303&origin=inward

U2 - 10.1016/j.orgel.2025.107283

DO - 10.1016/j.orgel.2025.107283

M3 - Article

VL - 144

JO - Organic Electronics: physics, materials, applications

JF - Organic Electronics: physics, materials, applications

SN - 1566-1199

M1 - 107283

ER -

ID: 67903056