Bilayer layer-by-layer structures for enhanced efficiency and stability of organic photovoltaics beyond bulk heterojunctions

被引：4

作者：

Kumari, Tanya ^{[1
,2
]}

Vyalih, Irina ^{[1
,2
]}

Luna, Miguel Angel Leon ^{[1
,2
]}

Ahmed, Hamsa ^{[1
,2
]}

Ahmad, Mariam ^{[1
,2
]}

Atajanov, Rovshen ^{[1
,2
]}

Jayaraman, Eswaran ^{[1
,2
]}

Manikandan, Suraj ^{[3
]}

Paci, Barbara ^{[4
]}

Di Carlo, Aldo ^{[4
,5
]}

Andreasen, Jens Wenzel ^{[3
]}

Turkovic, Vida ^{[1
,2
]}

Madsen, Morten ^{[1
,2
]}

机构：

[1] Univ Southern Denmark, Mads Clausen Inst, Ctr Adv Photovolta & Thin Film Energy Devices SDU, DK-6400 Sonderborg, Denmark

[2] Univ Southern Denmark, SDU Climate Cluster, DK-5230 Odense, Denmark

[3] Tech Univ Denmark, Dept Energy Convers & Storage, DK-2800 Lyngby, Denmark

[4] Ist Struttura Mat CNR, ISM CNR, Area Ric Roma Tor Vergata, Via Fosso Cavaliere 100, I-00133 Rome, Italy

[5] Univ Roma Tor Vergata, CHOSE Ctr Hybrid & Organ Solar Energy, Dept Elect Engn, Via Politecn 1, I-00133 Rome, Italy

来源：

CELL REPORTS PHYSICAL SCIENCE | 2024年 / 5卷 / 06期

关键词：

TERNARY SOLAR-CELLS; POLYMER; FULLERENE; ACCEPTOR; MORPHOLOGY; TEMPERATURE; SEPARATION; MODULE;

D O I：

10.1016/j.xcrp.2024.102027

中图分类号：

O6 [化学];

学科分类号：

0703 ;

摘要：

Tuning bulk heterojunctions is an important step for improving organic photovoltaic device performance; however, challenges remain in obtaining sufficient device lifetimes using this concept. In this work, we report on high-performance PM6/Y7 layer-by-layer organic photovoltaic devices by carefully tuning the layer-by-layer structure and studying the effects on device performance. We demonstrate that an optimized layer-by-layer organic photovoltaic can effectively improve the photophysical properties of the device, resulting in a conversion efficiency of 16.21%, surpassing the bulk heterojunction counterpart. Notably, the developed layer-by-layer device also outperforms the traditional bulk heterojunction in terms of long-term photostability and thermal stability under continuous illumination and temperature stress (85 degrees C) degrees C) for approximately 1,000 h, with similar results obtained for eight other non-fullerene acceptor systems. The improved longterm photostability and thermal stability in these layer-by-layer systems is ascribed to a mitigation of the strong phase aggregation seen in the bulk heterojunction films.

引用

页数：20

共 90 条

[21] Industrial viability of single-component organic solar cells
He, Yakun
Li, Ning
Heumueller, Thomas
Wortmann, Jonas
Hanisch, Benedict
Aubele, Anna
Lucas, Sebastian
Feng, Guitao
Jiang, Xudong
Li, Weiwei
Baeuerle, Peter
Brabec, Christoph J.
[J]. JOULE, 2022, 6 (06) : 1160 - 1171
[22] 25th Anniversary Article: Bulk Heterojunction Solar Cells: Understanding the Mechanism of Operation
Heeger, Alan J.
[J]. ADVANCED MATERIALS, 2014, 26 (01) : 10 - 28
[23] 18.5% Efficiency Organic Solar Cells with a Hybrid Planar/Bulk Heterojunction
Hong, Ling
Yao, Huifeng
Cui, Yong
Bi, Pengqing
Zhang, Tao
Cheng, Yongxin
Zu, Yunfei
Qin, Jinzhao
Yu, Runnan
Ge, Ziyi
Hou, Jianhui
[J]. ADVANCED MATERIALS, 2021, 33 (43)
[24] Charge carrier transport and nanomorphology control for efficient non-fullerene organic solar cells
Hu, Hanlin
Deng, Wanyuan
Qin, Minchao
Yin, Hang
Lau, Tsz-Ki
Fong, Patrick W. K.
Ren, Zhiwei
Liang, Qiong
Cui, Li
Wu, Hongbin
Lu, Xinhui
Zhang, Weimin
McCulloch, Iain
Li, Gang
[J]. MATERIALS TODAY ENERGY, 2019, 12 : 398 - 407
[25] Long-range exciton diffusion in a non-fullerene acceptor: approaching the incoherent limit
Hume, Paul A.
Jiao, Wanting
Hodgkiss, Justin M.
[J]. JOURNAL OF MATERIALS CHEMISTRY C, 2021, 9 (04) : 1419 - 1428
[26] 19.34 cm2 large-area quaternary organic photovoltaic module with 12.36% certified efficiency
Jia, Ziyan
Chen, Zeng
Chen, Xu
Yao, Jizhong
Yan, Buyi
Sheng, Rui
Zhu, Haiming
Yang, Yang
[J]. PHOTONICS RESEARCH, 2021, 9 (03) : 324 - 330
[27] Pseudo-bilayer architecture enables high-performance organic solar cells with enhanced exciton diffusion length
Jiang, Kui
Zhang, Jie
Peng, Zhengxing
Lin, Francis
Wu, Shengfan
Li, Zhen
Chen, Yuzhong
Yan, He
Ade, Harald
Zhu, Zonglong
Jen, Alex K. -Y.
[J]. NATURE COMMUNICATIONS, 2021, 12 (01)
[28] Stability of Polymer Solar Cells
Jorgensen, Mikkel
Norrman, Kion
Gevorgyan, Suren A.
Tromholt, Thomas
Andreasen, Birgitta
Krebs, Frederik C.
[J]. ADVANCED MATERIALS, 2012, 24 (05) : 580 - 612
[29] Amino-Functionalized Graphdiyne Derivative as a Cathode Interface Layer with High Thickness Tolerance for Highly Efficient Organic Solar Cells
Kan, Yuanyuan
Sun, Yanna
Ren, Yi
Xu, Yixuan
Jiang, Xinyue
Shen, Haojiang
Geng, Longlong
Li, Jianfeng
Cai, Ping
Xu, Huajun
Gao, Ke
Li, Yuliang
[J]. ADVANCED MATERIALS, 2024, 36 (16)
[30] Consensus statement for stability assessment and reporting for perovskite photovoltaics based on ISOS procedures
Khenkin, Mark V.
Katz, Eugene A.
Abate, Antonio
Bardizza, Giorgio
Berry, Joseph J.
Brabec, Christoph
Brunetti, Francesca
Bulovic, Vladimir
Burlingame, Quinn
Di Carlo, Aldo
Cheacharoen, Rongrong
Cheng, Yi-Bing
Colsmann, Alexander
Cros, Stephane
Domanski, Konrad
Dusza, Michal
Fell, Christopher J.
Forrest, Stephen R.
Galagan, Yulia
Di Girolamo, Diego
Graetzel, Michael
Hagfeldt, Anders
von Hauff, Elizabeth
Hoppe, Harald
Kettle, Jeff
Koebler, Hans
Leite, Marina S.
Liu, Shengzhong
Loo, Yueh-Lin
Luther, Joseph M.
Ma, Chang-Qi
Madsen, Morten
Manceau, Matthieu
Matheron, Muriel
McGehee, Michael
Meitzner, Rico
Nazeeruddin, Mohammad Khaja
Nogueira, Ana Flavia
Odabasi, Cagla
Osherov, Anna
Park, Nam-Gyu
Reese, Matthew O.
De Rossi, Francesca
Saliba, Michael
Schubert, Ulrich S.
Snaith, Henry J.
Stranks, Samuel D.
Tress, Wolfgang
Troshin, Pavel A.
Turkovic, Vida
[J]. NATURE ENERGY, 2020, 5 (01) : 35 - 49

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