Photovoltaic performance of novel Perovskite/organic integrated solar cells with high efficiency and high stability

Meng Jing; Gao Bo-Wen

doi:10.7498/aps.72.20221120

Abstract

Perovskite/organic integrated solar cell possesses the perovskite active layer with wide band gap that can absorb high energy photons, while the lower energy photons can pass through the perovskite layer and be absorbed by the organic active layer with narrow band gap. By introducing a Bulk heterojunction (BHJ) consisting of perovskite materials and near-infrared (NIR) organic semiconductor materials in the visible light region, the enhanced short-circuit current density of organic cells can be obtained while maintaining the high open-circuit voltage of perovskite-type devices. We prepare perovskite/organic integrated solar cells by directly deposing the narrow band gap organic active layer PC₂₀BDTDPP:PC₇₁BM on CH₃NH₃PbI₃. The CH₃NH₃PbI₃/PC₂₀BDTDPP:PC₇₁BM integrated solar cell can widen the perovskite absorption spectra, thereby increasing the near-infrared light absorption. The results show that the short-circuit current density of the integrated solar cell increases to 23.90 mA/cm², the optical response is widened to 920 nm, the external quantum efficiency reaches 85% in the visible region, and is close to 55% in the near infrared region (800–900 nm), and the energy conversion efficiency of the device increases up to 20.30%. The integrated current density, quantum efficiency, and energy conversion efficiency of the best device are the highest values ever reported in perovskite/organic integrated solar cells. At room temperature of 25 ℃ and humidity of 30%, the efficiency of the device decreases to 95% of the original efficiency after 350 h, showing excellent device stability. The results show that it is an effective method to improve the near-infrared absorption of perovskite solar cells and improve the performance of perovskite/organic integrated solar cells through material combination and device structure optimization. The present research provides theoretical guidance and experimental basis for the development of perovskite/ organic integrated cells with high efficiency and stability in the future.

Keywords:

perovskite/organic integrated solar cell /
near infrared absorption /
external quantum efficiency /
hysteresis effect

Authors and contacts

Meng Jing¹,
Gao Bo-Wen²

1.
Network and Educational Technology Center, Taishan University, Tai'an 271021, China
2.
Institute of Photovoltaic Materials and Building Integration, School of Mechanical and Civil Engineering, Taishan University, Tai'an 271021, China

Corresponding author: Meng Jing, mmmjjjcg@163.com ; Gao Bo-Wen, gbwhappy@163.com

Funds: Project supported by the Key Project of Natural Science Foundation of Shandong Province, China (Grant No. ZR2020KF001), the Science and Technology Innovation Development Project of Tai 'an City of Shandong Province, China (Grant No. 2021GX017), the Special Key Project of Education and Teaching Research of Taishan University (Grant No. JY-01-202101), the Teaching Reform and Research Project of Taishan University (Grant No. JG202122) and the Horizontal Research Project of Taishan University (Grant No. 2022HX222).

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References

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Cited By

图 1 聚合物PC₂₀BDTDPP合成以及PC₂₀BDTDPP:PCBM吸收光谱

Figure 1. Synthesis of polymer PC₂₀BDTDPP and absorption spectra of PC₂₀BDTDPP : PCBM.

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图 2 钙钛矿/有机集成太阳电池的器件结构与能级搭配图

Figure 2. Device structure and energy level collocation diagram of perovskite/organic integrated solar cell.

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图 3 钙钛矿/有机集成太阳电池有机层和钙钛矿层薄膜吸收光谱

Figure 3. Absorption spectra of organic layer and perovskite layer films of perovskite/organic integrated solar cell.

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图 4 钙钛矿/有机集成太阳电池薄膜的AFM和SEM测试

Figure 4. AFM and SEM of perovskite/organic integrated solar cell films.

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图 5 钙钛矿/有机集成太阳电池、单结电池光伏性能曲线以及迟滞现象

Figure 5. Photovoltaic performance curves and hysteresis of perovskite/organic integrated solar cells and single junction cells.

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图 6 钙钛矿/有机集成太阳电池和相应的单结电池外量子效率和稳定性测试曲线

Figure 6. External quantum efficiency and stability test curves of perovskite/organic integrated solar cells and corresponding single-junction cells.

DownLoad: Full-Size Img PowerPoint

表 1 钙钛矿/有机集成太阳电池和相应的单结电池光伏性能参数

Table 1. Photovoltaic performance parameters of perovskite/organic integrated solar cells and corresponding single-junction cells.

V_oc/V J_sc/(mA·cm^–2) FF/% PCE/%

PC₂₀BDTDPP:PC₇₁BM 0.91 15.02 66 9.21
CH₃NH₃PbI₃ 1.07 20.01 68 14.56
CH₃NH₃PbI₃/PC₂₀BDTDPP:PC₇₁BM(正扫) 1.18 23.90 72 20.30
CH₃NH₃PbI₃/PC₂₀BDTDPP:PC₇₁BM(反扫) 1.17 23.21 71 19.28

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[1]	Jeong J K, Kim M J, Seo J D, Lu H Z, Kim J Y, Grätzel M, Kim D S 2021 Nature 592 381 Google Scholar
[2]	Zhao Y, Ma F, Qu A H, You J B 2022 Science 377 531 Google Scholar
[3]	Liu Q S, Jiang Y F, Jin K, Qin J Q, Xu J G, Li W T, Xiong J, Liu J F, Xiao Z, Zhang X T, Ding L M 2020 Sci. Bull. 65 272 Google Scholar
[4]	Cai Y H, Li Y, Wang R, Wu H B, Sun Y M 2021 Adv. Mater. 33 2101733 Google Scholar
[5]	Bi P Q, Zhang S Q, Chen Z H, Hou J H 2021 Joule 5 1 Google Scholar
[6]	Gao K, Zhu Z L, Xu B, Jen A K Y 2018 Adv. Mater. 29 1703980 Google Scholar
[7]	Guo Q, Liu H, Shi Z Z, Wang F Z, Tan Z A 2018 Nanoscale 10 3245 Google Scholar
[8]	Wang C Y, Bai Y M, Guo Q, Tan Z A 2019 Nanoscale 11 4035
[9]	Liu Y, Chen Y 2020 Adv. Mater. 32 1805843 Google Scholar
[10]	Chen S, Yao H, Huang J, Ma W, Yan H 2018 Adv. Ener. Mater. 8 1800529 Google Scholar
[11]	Bai Y, Lang K, Zhao C, Alsaedi A, Tan Z A 2020 Solar RRL. 4 1900280 Google Scholar
[12]	Chen W, Sun H, Hu Q, Guo X, He Z 2019 ACS Energy Lett. 4 2535 Google Scholar
[13]	Gu S L, Lin R, Han Q, Gao Y, Zhu J 2020 Adv. Mater. 32 1907392 Google Scholar
[14]	Oklem G, Song X, Toppare L, Baran D, Gunbas G 2018 J. Mater. Chem. C 6 2957 Google Scholar
[15]	Meng L, Zhang Y, Wan X, Yi H L, Cao Y, Chen Y 2018 Science 361 1094 Google Scholar
[16]	Zhang L X, Pan X Y, Liu L, Ding L M 2022 J. Semicond. 43 030203 Google Scholar
[17]	Yuan J, Zhang Y, Peng H, Johnson PA, Leclerc M, Cao Y, 2019 Joule 3 1140 Google Scholar
[18]	Cui Y, Yao H F, Zhang J Q, Xian K H, Zhang T, Hong L, Wang Y M, Xu Y, Ma K Q, An C B, He C, Wei Z X, Gao F, Hou J H 2020 Adv. Mater. 32 1908205 Google Scholar
[19]	Daboczi M, McLachlan M A, Lee K, Durrant J R, Kim J S 2020 Adv. Funct. Mater. 30 2001482 Google Scholar

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