[1]王亞玲,閆翎鵬,董海亮,等.封裝對(duì)聚合物太陽能電池性能和穩(wěn)定性的影響[J].中國(guó)材料進(jìn)展,2023,42(05):398-405.[doi:10.7502/j.issn.1674-3962.202206016]
WANG Yaling,YAN Lingpeng,DONG Hailiang,et al.Encapsulation Effect on Performance and Stability of Organic Solar Cells[J].MATERIALS CHINA,2023,42(05):398-405.[doi:10.7502/j.issn.1674-3962.202206016]
點(diǎn)擊復(fù)制
封裝對(duì)聚合物太陽能電池性能和穩(wěn)定性的影響(
)
中國(guó)材料進(jìn)展[ISSN:1674-3962/CN:61-1473/TG]
- 卷:
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42
- 期數(shù):
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2023年第05期
- 頁(yè)碼:
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398-405
- 欄目:
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- 出版日期:
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2023-05-30
文章信息/Info
- Title:
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Encapsulation Effect on Performance and Stability of Organic Solar Cells
- 文章編號(hào):
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1674-3962(2023)05-0398-08
- 作者:
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王亞玲1; 2; 3; 閆翎鵬4; 董海亮2; 韓云飛3; 楊永珍2; 馬昌期3; 許并社2
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1.中北大學(xué)能源與動(dòng)力工程學(xué)院,山西 太原 030051
2.太原理工大學(xué) 新材料界面科學(xué)與工程教育部重點(diǎn)實(shí)驗(yàn)室�����,山西 太原 030024
3.中國(guó)科學(xué)院蘇州納米技術(shù)與納米仿生研究所 印刷電子研究中心,江蘇 蘇州 215123
4.太原理工大學(xué)材料科學(xué)與工程學(xué)院�����,山西 太原 030024
- Author(s):
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WANG Yaling1; 2; 3; YAN Lingpeng4; DONG Hailiang2; HAN Yunfei3; YANG Yongzhen2; MA Changqi3; XU Bingshe2
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1. School of Energy and Power Engineering����,North University of China���,Taiyuan 030051����,China
2. Key Laboratory of Interface Science and Engineering in Advanced Materials�����,Ministry of Education�,
Taiyuan University of Technology�����,Taiyuan 030024��,China
3. Printed Electronics Research Center�,Suzhou Institute of Nano-Tech and Nano-Bionics���,Chinese Academy of Sciences (CAS)��,Suzhou 215123,China
4. College of Materials Science and Engineering��,Taiyuan University of Technology�,Taiyuan 030024,China
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- 關(guān)鍵詞:
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封裝; 聚合物太陽能電池; UV膠; 三氧化鉬; 乙烯醋酸乙烯酯共聚物
- Keywords:
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encapsulation; organic solar cells; UV glue; molybdenum(VI) oxide; ethylenevinyl acetate copolymer
- 分類號(hào):
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TM914. 4
- DOI:
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10.7502/j.issn.1674-3962.202206016
- 文獻(xiàn)標(biāo)志碼:
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A
- 摘要:
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為了提高有機(jī)光伏器件的壽命,通常采用封裝技術(shù)來限制太陽能電池在水氧中的暴露程度���。盡管聚合物太陽能電池(organic solar cells����,OSCs)封裝領(lǐng)域的相關(guān)研究已取得系列進(jìn)展��,但文獻(xiàn)中很少研究封裝過程帶來的損傷�。以經(jīng)典的聚-3已基噻吩為給體,[6,6]-苯基-C61-丁酸甲酯為受體��,通過將哌嗪作為第三組分提高器件穩(wěn)定性�,以氧化鋅(ZnO)和三氧化鉬(MoO3)為傳輸層材料制備倒置結(jié)構(gòu)OSCs,系統(tǒng)考察大規(guī)模卷對(duì)卷器件封裝中常用的紫外線(ultraviolet����,UV)固化粘合劑對(duì)器件光電轉(zhuǎn)化效率和穩(wěn)定性的影響。結(jié)果表明��,隨著輻照時(shí)間的延長(zhǎng)����,UV膠封裝器件的性能(開路電壓���、短路電流密度����、填充因子和光電轉(zhuǎn)化效率)呈持續(xù)下降趨勢(shì)����,更換MoO3/Al電極后老化器件性能恢復(fù)�,證實(shí)MoO3/Al界面破壞是器件性能衰減的重要原因��。激光束誘導(dǎo)電流成像顯示UV膠封裝出現(xiàn)由邊緣向中心的失效過程����。據(jù)此�,提出如下的降解機(jī)理:UV膠中的光引發(fā)劑在紫外光照射下會(huì)產(chǎn)生強(qiáng)的質(zhì)子酸����,產(chǎn)生的質(zhì)子酸與MoO3發(fā)生反應(yīng)��,阻礙了空穴的有效傳輸����,最終使得器件效率大幅度下降��。此外�,還開發(fā)出一種有效的OSCs器件用乙烯醋酸乙烯酯共聚物膜封裝工藝。本研究指出了UV膠固化粘合劑封裝工藝的問題�����,同時(shí)也為提高聚合物太陽能電池的穩(wěn)定性提供了新策略�����。
- Abstract:
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In order to improve the lifetime of organic photovoltaic devices, encapsulation technology is often used to limit the exposure of solar cells to water and oxygen. Despite a series of advances in the encapsulation field of organic solar cells (OSCs), the damage caused by the encapsulation process has rarely been studied in the literature. In this paper, inverted OSCs with high stability were prepared by using classical poly(3-hexylthiophene) as the donor, [6,6]phenyl-C61-butyric acid methyl ester as the acceptor, piperazine that can improve stability of device as the third component, zinc oxide (ZnO) and molybdenum trioxide (MoO3) as the transport layer material. The effect of ultraviolet (UV) curing adhesive commonly used in large-scale roll-to-roll device encapsulating on the photoelectric conversion efficiency and stability is systematically investigated. The results are as follows: the performance (such as open-circuit voltage, short-circuit current density, fill factor, and power conversion efficiency) of UV glue-encapsulated devices shows a continuous decline with the prolongation of the irradiation time. Meanwhile, the performance of the aging devices is restored after replacing the MoO3/Al electrode, which confirms that the MoO3/Al interface corruption is an important reason for the performance attenuation of the device. Laser beam induced current imaging shows a center-to-edge failure process in UV glue-encapsulated device. Based on this, the following degradation mechanism is proposed: the photoinitiator in the UV glue will generate a strong protonic acid under UV light irradiation, and react with MoO3, which hinders the effective transmission of the hole, and ultimately reduces the device efficiency significantly. In addition, an effective ethylene-vinyl acetate copolymer encapsulation process for OSCs devices has also been developed. This study provides a new understanding of the UV glue encapsulation process, and also develops a new strategy for improving the stability of organic solar c
參考文獻(xiàn)/References:
[1]WANG J Y�����,LIU K�,MA L C�����,et al.Chemical Reviews[J]��,2016���,116(23):14675-14725.
[2]YE L�,ZHANG S Q��,HUO L J��,et al.Accounts of Chemical Research[J]�����,2014��,47(5):1595-1603.
[3]GUO F�����,LI N,F(xiàn)ECHER F W�,et al.Nature Communications[J],2015����,6:7730.
[4]ZHANG X,LI W P���,YAO J N,et al.ACS Applied Materials & Interfaces[J]�,2016,8(24):15415-15421.
[5]GRAETZEL M���,JANSSEN R A J��,MITZI D B����,et al.Nature[J]����,2012,488(7411):304-312.
[6]LI C�����,ZHOU J��,SONG J��,et al.Nature Energy[J]��,2021��,6(6):605-613.
[7]MENG H�,LIAO C,DENG M��,et al.Angewandte ChemieInternational Edition[J]����,2021,133(41):22728-22735.
[8]CUI Y�,XU Y,YAO H����,et al.Advanced Materials[J]����,2021,33(41):2102420.
[9]ZHENG Z���,WANG J,BI P�����,et al.Joule[J]��,2022��,6:171-184.
[10]GROSSIORD N���,KROON J M�����,ANDRIESSEN R���,et al.Advanced Engineering Materials[J]����,2013,15(11):1068-1075.
[11]劉彥甫����,李世麟,荊亞楠���,等.化學(xué)學(xué)報(bào)[J/OL].(2022-04-22)[2022-06-27].https://kns.cnki.net/kcms/detail/31.1320.O6.20220421.1632.002.html.
LIU Y F�,LI S L����,JING Y N���,et al.Acta Chimica Sinica[J/OL].(2022-04-22)[2022-06-27].https://kns.cnki.net/kcms/detail/31.1320.O6.20220421.1632002.html.
[12]YU Z P�����,LIU Z X�,CHEN F X�����,et al.Nature Communications[J]�����,2019�,10(1):1-9.
[13]LIU Z X,YU Z P����,SHEN Z�����,et al.Nature Communications[J]�����,2021����,12(1):1-10.
[14]MING S,WU H�,WANG X,et al.Journal of Materials Chemistry A[J]����,2020�����,8(43):22907-22917.
[15]CHENG P����,ZHAN X.Materials Horizons[J],2015�,2(5):462-485.
[16]YAN L���,WANG Y�,WEI J,et al.Journal of Materials Chemistry A[J]��,2019����,7(12):7099-7108.
[17]YIN Z,MEI S���,GU P,et al.iScience[J]�,2021,24(9):103027.
[18]AHMAD J����,BAZAKA K,ANDERSON L J��,et al.Renewable and Sustainable Energy Reviews[J]����,2013��,27:104-117.
[19]KIM N�����,POTSCAVAGE J W J�,SUNDARAMOOTHI A,et al.Solar Energy Materials and Solar Cells[J]��,2012����,101:140-146.
[20]KOVROV A�����,HELGESEN M�,BOEFFEL C,et al.Solar Energy Materials and Solar Cells[J]���,2020,204:110210.
[21]PLANES E���,JUILLARD S���,MATHERON M���,et al.Advanced Materials Interfaces[J],2020�����,7(15):2000293.
[22]HSEL M�����,SNDERGAARD R R����,JRGENSEN M��,et al.Advanced Engineering Materials[J]���,2013,15(11):1068-1075.
[23]PETERS C H���,SACHSQUINTANA I T��,KASTROP J P���,et al.Advanced Energy Materials[J],2011�����,1(4):491-494.
[24]KONG J��,SONG S����,YOO M���,et al.Nature Communications[J]�����,2014�,5(1):1-8.
\[25\]閆翎鵬�,趙文盛���,楊永珍���,等.高分子學(xué)報(bào)\[J\]��,2021���,52(4):350-362.
YAN L P�����,ZHAO W S���,YANG Y Z�����,et al.Acta Polymerica Sinica\[J\]���,2021,52(4):350-362.
\[26\]HEUMUELLER T��,MATEKER W R�,DISTLER A,et al.Energy & Environmental Science\[J\]�����,2016�,9(1):247-256.
\[27\]MATEKER W R�����,DOUGLAS J D��,CABANETOS C���,et al.Energy & Environmental Science\[J\],2013�����,6(8):2529-2537.
\[28\]SACHSQUINTANA I T��,HEUMLLER T���,MATEKER W R,et al.Advanced Functional Materials\[J\],2014�,24(25):3978-3985.
備注/Memo
- 備注/Memo:
-
收稿日期: 2022-06-28 修回日期: 2022-08-11
基金項(xiàng)目: 國(guó)家自然科學(xué)基金青年科學(xué)基金項(xiàng)目(61904121); 山西
省應(yīng)用基礎(chǔ)研究計(jì)劃面上青年基金項(xiàng)目(201901D211282);
中北大學(xué)2019 年校科研基金項(xiàng)目(XJJ201925)
第一作者: 王亞玲, 女, 1990 年生, 博士, 講師
通訊作者: 楊永珍, 女, 1969 年生, 教授, 博士生導(dǎo)師,
Email: yyztyut@ 126. com
馬昌期, 男, 1976 年生, 研究員, 博士生導(dǎo)師,
Email: cqma2011@ sinano. ac. cn
更新日期/Last Update:
2023-05-10