Full Text:   <501>

Summary:  <89>

CLC number: 

On-line Access: 2024-10-30

Received: 2024-01-10

Revision Accepted: 2024-03-18

Crosschecked: 2024-10-30

Cited: 0

Clicked: 662

Citations:  Bibtex RefMan EndNote GB/T7714

 ORCID:

Lijian ZUO

https://orcid.org/0000-0003-0338-1198

-   Go to

Article info.
Open peer comments

Journal of Zhejiang University SCIENCE A 2024 Vol.25 No.10 P.841-853

http://doi.org/10.1631/jzus.A2400015


High-performance and multifunctional organic photovoltaic devices


Author(s):  Yiming WANG, Lijian ZUO

Affiliation(s):  State Key Laboratory of Silicon Materials, Department of Polymer Science and Engineering, Zhejiang University, Hangzhou 310027, China; more

Corresponding email(s):   zjuzlj@zju.edu.cn

Key Words:  Organic photovoltaic, Multi-component, Semitransparent, Flexibility


Yiming WANG, Lijian ZUO. High-performance and multifunctional organic photovoltaic devices[J]. Journal of Zhejiang University Science A, 2024, 25(10): 841-853.

@article{title="High-performance and multifunctional organic photovoltaic devices",
author="Yiming WANG, Lijian ZUO",
journal="Journal of Zhejiang University Science A",
volume="25",
number="10",
pages="841-853",
year="2024",
publisher="Zhejiang University Press & Springer",
doi="10.1631/jzus.A2400015"
}

%0 Journal Article
%T High-performance and multifunctional organic photovoltaic devices
%A Yiming WANG
%A Lijian ZUO
%J Journal of Zhejiang University SCIENCE A
%V 25
%N 10
%P 841-853
%@ 1673-565X
%D 2024
%I Zhejiang University Press & Springer
%DOI 10.1631/jzus.A2400015

TY - JOUR
T1 - High-performance and multifunctional organic photovoltaic devices
A1 - Yiming WANG
A1 - Lijian ZUO
J0 - Journal of Zhejiang University Science A
VL - 25
IS - 10
SP - 841
EP - 853
%@ 1673-565X
Y1 - 2024
PB - Zhejiang University Press & Springer
ER -
DOI - 10.1631/jzus.A2400015


Abstract: 
organic photovoltaic devices (OPVs) are emerging as a promising renewable energy source for the future. Their unique advantages, such as semitransparency, light weight, superior flexibility, and low cost, enable a wide range of applications. However, compared to silicon-based photovoltaics, OPVs still face challenges for further improving their efficiency. Additionally, there is a need to explore their potential of multi-functionality for practical application in various scenarios. This review summarizes the recent achievements in optimizing device performance and enhancing power-conversion efficiency, particularly via tuning the intermolecular interaction to reduce the electron-vibration coupling and non-radiative charge recombination (denoted as the “dilution effect”). Moreover, the representative development of ultra-thin Ag transparent electrode-based OPVs with multi-functional capabilities (such as semitransparency, flexibility, stretchability, and better aesthetics) has also been covered. Therefore, this review aims to provide a broad landscape on the recent development of OPV and to unlock the full potential of OPVs.

高性能多功能有机光伏器件

作者:王一鸣1,左立见1,2
机构:1浙江大学,高分子科学与工程系,硅材料国家重点实验室,中国杭州,310027;2浙江大学-杭州市全球科技创新中心,中国杭州,310014
概要:基于半透明性、轻量化、优异的柔性和低成本等优点,有机光伏器件被视为下一代可再生能源的有望来源,因此其在未来拥有更多样化的应用前景。与主流的硅基光伏技术相比,有机光伏器件的效率仍需提高,且其在广泛场景中应用多功能性的潜力也需要进一步的探索。本综述总结了近些年取得的研究成果,重点关注如何进一步提高器件效率,并开发具备多功能性(如半透明性、柔性、可拉伸性和美观性等)的有机光伏器件。

关键词:有机光伏;多组分;半透明;柔性

Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article

Reference

[1]AmirkhaniS, Bahadori-JahromiA, MylonaA, et al., 2019. Impact of Low-E window films on energy consumption and CO2 emissions of an existing UK hotel building. Sustainability, 11(16):4265.

[2]BenduhnJ, TvingstedtK, PiersimoniF, et al., 2017. Intrinsic non-radiative voltage losses in fullerene-based organic solar cells. Nature Energy, 2(6):17053.

[3]BulovićV, DeshpandeR, ThompsonME, et al., 1999. Tuning the color emission of thin film molecular organic light emitting devices by the solid state solvation effect. Chemical Physics Letters, 308(3-4):317-322.

[4]BulovićV, ShoustikovA, BaldoMA, et al., 1998. Bright, saturated, red-to-yellow organic light-emitting devices based on polarization-induced spectral shifts. Chemical Physics Letters, 287(3-4):455-460.

[5]ChangYL, ZhuXW, ZhuLY, et al., 2021. Regioregular narrow bandgap copolymer with strong aggregation ability for high-performance semitransparent photovoltaics. Nano Energy, 86:106098.

[6]ChenTY, LiSX, LiYK, et al., 2023. Compromising charge generation and recombination of organic photovoltaics with mixed diluent strategy for certified 19.4% efficiency. Advanced Materials, 35(21):e2300400.

[7]DattR, LeeHKH, ZhangGC, et al., 2022. Organic solar cells at stratospheric condition for high altitude platform station application. Chinese Journal of Chemistry, 40(24):2927-2932.

[8]de JongM, SeijoL, MeijerinkA, et al., 2015. Resolving the ambiguity in the relation between Stokes shift and Huang-Rhys parameter. Physical Chemistry Chemical Physics, 17(26):16959-16969.

[9]FukudaK, YuK, SomeyaT, 2020. The future of flexible organic solar cells. Advanced Energy Materials, 10(25):2000765.

[10]GuanST, LiYK, YanKR, et al., 2022. Balancing the selective absorption and photon-to-electron conversion for semitransparent organic photovoltaics with 5.0% light-utilization efficiency. Advanced Materials, 34(41):2205844.

[11]GüntherM, KazerouniN, BlätteD, et al., 2023. Models and mechanisms of ternary organic solar cells. Nature Reviews Materials, 8(7):456-471.

[12]HeCL, ChenZ, WangTH, et al., 2022a. Asymmetric electron acceptor enables highly luminescent organic solar cells with certified efficiency over 18%. Nature Communications, 13(1):2598.

[13]HeCL, PanYW, OuyangYN, et al., 2022b. Manipulating the D:A interfacial energetics and intermolecular packing for 19.2% efficiency organic photovoltaics. Energy & Environmental Science, 15(6):2537-2544.

[14]HongYN, LamJWY, TangBZ, 2009. Aggregation-induced emission: phenomenon, mechanism and applications. Chemical Communications, (29):4332-4353.

[15]HongYN, LamJWY, TangBZ, 2011. Aggregation-induced emission. Chemical Society Reviews, 40(11):5361-5388.

[16]HuangJM, LuZ, HeJQ, et al., 2023. Intrinsically stretchable, semi-transparent organic photovoltaics with high efficiency and mechanical robustness via a full-solution process. Energy & Environmental Science, 16(3):1251-1263.

[17]HuangY, KramerEJ, HeegerAJ, et al., 2014. Bulk heterojunction solar cells: morphology and performance relationships. Chemical Reviews, 114(14):7006-7043.

[18]KumarA, DevineR, MayberryC, et al., 2010. Origin of radiation-induced degradation in polymer solar cells. Advanced Functional Materials, 20(16):2729-2736.

[19]LeeK, KimN, KimK, et al., 2020. Neutral-colored transparent crystalline silicon photovoltaics. Joule, 4(1):235-246.

[20]LiYK, GuoY, ChenZ, et al., 2022. Mechanism study on organic ternary photovoltaics with 18.3% certified efficiency: from molecule to device. Energy & Environmental Science, 15(2):855-865.

[21]LiYK, HeCL, ZuoLJ, et al., 2021. High-performance semi-transparent organic photovoltaic devices via improving absorbing selectivity. Advanced Energy Materials, 11(11):2003408.

[22]LimDH, HaJW, ChoiH, et al., 2021. Recent progress of ultra-narrow-bandgap polymer donors for NIR-absorbing organic solar cells. Nanoscale Advances, 3(15):4306-4320.

[23]LiuS, YuanJ, DengWY, et al., 2020. High-efficiency organic solar cells with low non-radiative recombination loss and low energetic disorder. Nature Photonics, 14(5):300-305.

[24]LiuX, ZhongZP, ZhuRH, et al., 2022. Aperiodic band-pass electrode enables record-performance transparent organic photovoltaics. Joule, 6(8):1918-1930.

[25]LiuY, ZuoLJ, ShiXL, et al., 2018. Unexpectedly slow yet efficient picosecond to nanosecond photoinduced hole-transfer occurs in a polymer/nonfullerene acceptor organic photovoltaic blend. ACS Energy Letters, 3(10):2396-2403.

[26]MakaAOM, AlabidJM, 2022. Solar energy technology and its roles in sustainable development. Clean Energy, 6(3):476-483.

[27]NortheyT, StaceyJ, PenfoldTJ, 2017. The role of solid state solvation on the charge transfer state of a thermally activated delayed fluorescence emitter. Journal of Materials Chemistry C, 5(42):11001-11009.

[28]ParkSH, RoyA, BeaupréS, et al., 2009. Bulk heterojunction solar cells with internal quantum efficiency approaching 100%. Nature Photonics, 3(5):297-302.

[29]ScharberMC, SariciftciNS, 2021. Low band gap conjugated semiconducting polymers. Advanced Materials Technologies, 6(4):2000857.

[30]ShiXL, ZuoLJ, JoSB, et al., 2017. Design of a highly crystalline low-band gap fused-ring electron acceptor for high-efficiency solar cells with low energy loss. Chemistry of Materials, 29(19):8369-8376.

[31]SinghV, RayalI, Priyanaka, et al., 2020. Chapter 1–solar radiation and light materials interaction. In: Dalapati GK, Sharma M (Eds.), Energy Saving Coating Materials. Elsevier, p.1-32.

[32]TakS, WooS, ParkJ, et al., 2017. Effect of the changeable organic semi-transparent solar cell window on building energy efficiency and user comfort. Sustainability, 9(6):950.

[33]TraverseCJ, PandeyR, BarrMC, et al., 2017. Emergence of highly transparent photovoltaics for distributed applications. Nature Energy, 2(11):849-860.

[34]VandewalK, TvingstedtK, GadisaA, et al., 2009. On the origin of the open-circuit voltage of polymer–fullerene solar cells. Nature Materials, 8(11):904-909.

[35]VeldmanD, İpekÖ, MeskersSCJ, et al., 2008. Compositional and electric field dependence of the dissociation of charge transfer excitons in alternating polyfluorene copolymer/fullerene blends. Journal of the American Chemical Society, 130(24):7721-7735.

[36]VictoriaM, HaegelN, PetersIM, et al., 2021. Solar photovoltaics is ready to power a sustainable future. Joule, 5(5):1041-1056.

[37]WangD, LiuHR, LiYH, et al., 2021. High-performance and eco-friendly semitransparent organic solar cells for greenhouse applications. Joule, 5(4):945-957.

[38]WangYM, YuJW, ZhangR, et al., 2023. Origins of the open-circuit voltage in ternary organic solar cells and design rules for minimized voltage losses. Nature Energy, 8(9):978-988.

[39]XuCY, JinK, XiaoZ, et al., 2021. Wide bandgap polymer with narrow photon harvesting in visible light range enables efficient semitransparent organic photovoltaics. Advanced Functional Materials, 31(52):2107934.

[40]YangF, HuangYT, LiYW, et al., 2021. Large-area flexible organic solar cells. npj Flexible Electronics, 5(1):30.

[41]YeQR, ChenZY, YangDB, et al., 2023. Ductile oligomeric acceptor-modified flexible organic solar cells show excellent mechanical robustness and near 18% efficiency. Advanced Materials, 35(44):2305562.

[42]YuanYB, ReeceTJ, SharmaP, et al., 2011. Efficiency enhancement in organic solar cells with ferroelectric polymers. Nature Materials, 10(4):296-302.

[43]ZhanLL, LiSX, LiYK, et al., 2022. Desired open-circuit voltage increase enables efficiencies approaching 19% in symmetric-asymmetric molecule ternary organic photovoltaics. Joule, 6(3):662-675.

[44]ZhangHT, TianP, ZhongJ, et al., 2023. Mapping photovoltaic panels in coastal China using Sentinel-1 and Sentinel-2 images and Google Earth Engine. Remote Sensing, 15(15):3712.

[45]ZhangYN, LuoD, ShanCW, et al., 2022. High-performance semitransparent organic solar cells enabled by improved charge transport and optical engineering of ternary blend active layer. Solar RRL, 6(1):2100785.

[46]ZhangZX, ChenM, ZhongT, et al., 2023. Carbon mitigation potential afforded by rooftop photovoltaic in China. Nature Communications, 14(1):2347.

[47]ZhaoF, ZuoLJ, LiYK, et al., 2021. High-performance upscaled indium tin oxide-free organic solar cells with visual esthetics and flexibility. Solar RRL, 5(9):2100339.

[48]ZhaoF, ZhengXJ, LiSX, et al., 2022. Non-halogenated solvents processed efficient ITO-free flexible organic solar cells with upscaled area. Macromolecular Rapid Communications, 43(16):2200049.

[49]ZhengXJ, ZuoLJ, ZhaoF, et al., 2022. High-efficiency ITO-free organic photovoltaics with superior flexibility and upscalability. Advanced Materials, 34(17):2200044.

[50]ZhengXJ, ZuoLJ, YanKR, et al., 2023. Versatile organic photovoltaics with a power density of nearly 40 W g-1. Energy & Environmental Science, 16(5):2284-2294.

[51]ZhengXJ, WuXL, WuQ, et al., 2024. Thorough optimization for intrinsically stretchable organic photovoltaics. Advanced Materials, 36(11):2307280.

[52]ZhongQ, NelsonJR, TongDQ, et al., 2022. A spatial optimization approach to increase the accuracy of rooftop solar energy assessments. Applied Energy, 316:119128.

[53]ZuoLJ, ChuehCC, XuYX, et al., 2014. Microcavity-enhanced light-trapping for highly efficient organic parallel tandem solar cells. Advanced Materials, 26(39):6778-6784.

[54]ZuoLJ, JoSB, LiYK, et al., 2022. Dilution effect for highly efficient multiple-component organic solar cells. Nature Nanotechnology, 17(1):53-60.

Open peer comments: Debate/Discuss/Question/Opinion

<1>

Please provide your name, email address and a comment





Journal of Zhejiang University-SCIENCE, 38 Zheda Road, Hangzhou 310027, China
Tel: +86-571-87952783; E-mail: cjzhang@zju.edu.cn
Copyright © 2000 - 2024 Journal of Zhejiang University-SCIENCE