Eliminating the Burn-in Loss of Efficiency in Organic Solar Cells by Applying Dimer Acceptors as Supramolecular Stabilizers

Yanxun Li; Feng Qi; Baobing Fan; Kai Kai Liu; Jifa Yu; Yuang Fu; Xianzhao Liu; Zhen Wang; Sen Zhang; Guanghao Lu; Xinhui Lu; Qunping Fan; Philip C.Y. Chow; Wei Ma; Francis R. Lin; Alex K.Y. Jen

doi:10.1002/adma.202313393

Eliminating the Burn-in Loss of Efficiency in Organic Solar Cells by Applying Dimer Acceptors as Supramolecular Stabilizers

Yanxun Li
, Feng Qi
, Baobing Fan
, Kai Kai Liu
, Jifa Yu
, Yuang Fu
, Xianzhao Liu
, Zhen Wang
, Sen Zhang
, Guanghao Lu
, Xinhui Lu
, Qunping Fan
, Philip C.Y. Chow
, Wei Ma
, Francis R. Lin
, Alex K.Y. Jen^*

^*此作品的通讯作者

City University of Hong Kong
Qingdao University
Xi'an Jiaotong University
Chinese University of Hong Kong
The University of Hong Kong
University of Washington

科研成果: 期刊稿件 › 文章 › 同行评审

43 引用（Scopus）

摘要

The meta-stable active layer morphology of organic solar cells (OSCs) is identified as the main cause of the rapid burn-in loss of power conversion efficiency (PCE) during long-term device operation. However, effective strategies to eliminate the associated loss mechanisms from the initial stage of device operation are still lacking, especially for high-efficiency material systems. Herein, the introduction of molecularly engineered dimer acceptors with adjustable thermal transition properties into the active layer of OSCs to serve as supramolecular stabilizers for regulating the thermal transitions and optimizing the crystallization of the absorber composites is reported. By establishing intimate π-π interactions with small-molecule acceptors, these stabilizers can effectively reduce the trap-state density (N_t) in the devices to achieve excellent PCEs over 19%. More importantly, the low N_t associated with an initially optimized morphology can be maintained under external stresses to significantly reduce the PCE burn-in loss in devices. This research reveals a judicious approach to improving OPV stability by establishing a comprehensive correlation between material properties, active-layer morphology, and device performance, for developing burn-in-free OSCs.

源语言	英语
文章编号	2313393
期刊	Advanced Materials
卷	36
期	23
DOI	https://doi.org/10.1002/adma.202313393
出版状态	已出版 - 6 6月 2024
已对外发布	是

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Li, Y., Qi, F., Fan, B., Liu, K. K., Yu, J., Fu, Y., Liu, X., Wang, Z., Zhang, S., Lu, G., Lu, X., Fan, Q., Chow, P. C. Y., Ma, W., Lin, F. R., & Jen, A. K. Y. (2024). Eliminating the Burn-in Loss of Efficiency in Organic Solar Cells by Applying Dimer Acceptors as Supramolecular Stabilizers. Advanced Materials, 36(23), 文章 2313393. https://doi.org/10.1002/adma.202313393

@article{5d3aa598c3b84fd1bea6427b244e7abb,

title = "Eliminating the Burn-in Loss of Efficiency in Organic Solar Cells by Applying Dimer Acceptors as Supramolecular Stabilizers",

abstract = "The meta-stable active layer morphology of organic solar cells (OSCs) is identified as the main cause of the rapid burn-in loss of power conversion efficiency (PCE) during long-term device operation. However, effective strategies to eliminate the associated loss mechanisms from the initial stage of device operation are still lacking, especially for high-efficiency material systems. Herein, the introduction of molecularly engineered dimer acceptors with adjustable thermal transition properties into the active layer of OSCs to serve as supramolecular stabilizers for regulating the thermal transitions and optimizing the crystallization of the absorber composites is reported. By establishing intimate π-π interactions with small-molecule acceptors, these stabilizers can effectively reduce the trap-state density (Nt) in the devices to achieve excellent PCEs over 19\%. More importantly, the low Nt associated with an initially optimized morphology can be maintained under external stresses to significantly reduce the PCE burn-in loss in devices. This research reveals a judicious approach to improving OPV stability by establishing a comprehensive correlation between material properties, active-layer morphology, and device performance, for developing burn-in-free OSCs.",

keywords = "burn-in loss, dimer acceptor, organic photovoltaics, supramolecular stabilizer, thermal transition, trap state",

author = "Yanxun Li and Feng Qi and Baobing Fan and Liu, \{Kai Kai\} and Jifa Yu and Yuang Fu and Xianzhao Liu and Zhen Wang and Sen Zhang and Guanghao Lu and Xinhui Lu and Qunping Fan and Chow, \{Philip C.Y.\} and Wei Ma and Lin, \{Francis R.\} and Jen, \{Alex K.Y.\}",

note = "Publisher Copyright: {\textcopyright} 2024 Wiley-VCH GmbH.",

year = "2024",

month = jun,

day = "6",

doi = "10.1002/adma.202313393",

language = "英语",

volume = "36",

journal = "Advanced Materials",

issn = "0935-9648",

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T1 - Eliminating the Burn-in Loss of Efficiency in Organic Solar Cells by Applying Dimer Acceptors as Supramolecular Stabilizers

AU - Li, Yanxun

AU - Qi, Feng

AU - Fan, Baobing

AU - Liu, Kai Kai

AU - Yu, Jifa

AU - Fu, Yuang

AU - Liu, Xianzhao

AU - Wang, Zhen

AU - Zhang, Sen

AU - Lu, Guanghao

AU - Lu, Xinhui

AU - Fan, Qunping

AU - Chow, Philip C.Y.

AU - Ma, Wei

AU - Lin, Francis R.

AU - Jen, Alex K.Y.

PY - 2024/6/6

Y1 - 2024/6/6

N2 - The meta-stable active layer morphology of organic solar cells (OSCs) is identified as the main cause of the rapid burn-in loss of power conversion efficiency (PCE) during long-term device operation. However, effective strategies to eliminate the associated loss mechanisms from the initial stage of device operation are still lacking, especially for high-efficiency material systems. Herein, the introduction of molecularly engineered dimer acceptors with adjustable thermal transition properties into the active layer of OSCs to serve as supramolecular stabilizers for regulating the thermal transitions and optimizing the crystallization of the absorber composites is reported. By establishing intimate π-π interactions with small-molecule acceptors, these stabilizers can effectively reduce the trap-state density (Nt) in the devices to achieve excellent PCEs over 19%. More importantly, the low Nt associated with an initially optimized morphology can be maintained under external stresses to significantly reduce the PCE burn-in loss in devices. This research reveals a judicious approach to improving OPV stability by establishing a comprehensive correlation between material properties, active-layer morphology, and device performance, for developing burn-in-free OSCs.

AB - The meta-stable active layer morphology of organic solar cells (OSCs) is identified as the main cause of the rapid burn-in loss of power conversion efficiency (PCE) during long-term device operation. However, effective strategies to eliminate the associated loss mechanisms from the initial stage of device operation are still lacking, especially for high-efficiency material systems. Herein, the introduction of molecularly engineered dimer acceptors with adjustable thermal transition properties into the active layer of OSCs to serve as supramolecular stabilizers for regulating the thermal transitions and optimizing the crystallization of the absorber composites is reported. By establishing intimate π-π interactions with small-molecule acceptors, these stabilizers can effectively reduce the trap-state density (Nt) in the devices to achieve excellent PCEs over 19%. More importantly, the low Nt associated with an initially optimized morphology can be maintained under external stresses to significantly reduce the PCE burn-in loss in devices. This research reveals a judicious approach to improving OPV stability by establishing a comprehensive correlation between material properties, active-layer morphology, and device performance, for developing burn-in-free OSCs.

KW - burn-in loss

KW - dimer acceptor

KW - organic photovoltaics

KW - supramolecular stabilizer

KW - thermal transition

KW - trap state

UR - https://www.scopus.com/pages/publications/85190282813

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DO - 10.1002/adma.202313393

M3 - 文章

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AN - SCOPUS:85190282813

SN - 0935-9648

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JO - Advanced Materials

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Eliminating the Burn-in Loss of Efficiency in Organic Solar Cells by Applying Dimer Acceptors as Supramolecular Stabilizers

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