TEAOH界面修饰制备高效FAPbBr3钙钛矿太阳能电池

doi:10.6023/A25100347

研究论文

TEAOH界面修饰制备高效FAPbBr₃钙钛矿太阳能电池

汪佳艳^a, 郭焕焕^*,b, 殷逍遥^a, 张昀照^a, 王威^a, 赵晨瑞^a, 陈洁^a, 文洁^a, 孙伟海^*,a

^a华侨大学材料科学与工程学院物理化学研究所,环境友好功能材料教育部工程研究中心,福建省光电功能材料重点实验室厦门 361021;
^b邢台学院化学工程与生物技术学院河北邢台 054001

投稿日期:2025-10-19
基金资助:
国家自然科学基金(No.61804058),华侨大学中青年教师科研提升资助计划(ZQN-706),河北省教育厅科学研究项目(BJK2022068),河北省引进留学人员资助项目(C20220306),邢台学院教育教学研究与实践项目(JGZ24002)

Preparation of High-Efficiency FAPbBr₃ Perovskite Solar Cells via TEAOH Interface Modification

Wang Jiayan^a, GUO Huanhuan^*,b, Yin Xiaoyao^a, Zhang Yunzhao^a, Wang Wei^a, Zhao Chenrui^a, Chen Jie^a, Wen Jie^a, Sun Weihai^*,a

^aSchool of Materials Science and Engineering, Huaqiao University, Engineering Research Center of Environment-FriendlyFunctional Materials, Ministry of Education. Fujian Key Laboratory of Photoelectric Functional Materials, Institute of Materials Physical Chemistry, Xiamen; School of Chemical Engineering and Biotechnology;
^bXingtai University, Xingtai, Hebei 054001, China

Received:2025-10-19
Contact: ^*E-mail: sunweihai@hqu.edu.cn
Supported by:
National Natural Science Foundation of China (No. 61804058),Young and Middle-aged Teachers' Scientific Research Promotion Program of Huaqiao University (ZQN-706),Scientific Research Project of the Education Department of Hebei Province (BJK2022068),Overseas Returnees Support Program of Hebei Province (C20220306),Education and Teaching Research and Practice Project of Xingtai University (JGZ24002)

文章分享

1. 附件.pdf(248KB)

摘要/Abstract

近些年来,甲脒溴化铅(FAPbBr₃)钙钛矿太阳能电池凭借着较宽的带隙、出色的环境稳定性以及较高的开路电压,在叠层电池、半透明器件以及光催化等多个领域受到了广泛的关注。本研究采用两步溶液旋涂法制备FAPbBr₃钙钛矿薄膜,在TiO₂电子传输层上引入了四乙基氢氧化铵(TEAOH)作为界面修饰剂。通过系统的表征分析发现,TEAOH溶液浓度为4 mg·mL^-1时达到最佳光伏性能,展现出显著的形貌改善,直接导致了薄膜质量的提升,缺陷态密度更低,从而抑制了载流子的复合。最终制备最优器件,开路电压(open-circuit voltage, V_OC)为1.63 V,短路电流密度(short-circuit current density, J_SC)为7.99 mA·cm^-2,填充因子(fill factor, FF)为83.74%,光电转换效率(photoelectric conversion efficiency, PCE)达10.91%,并且目前该值是在无空穴传输层(hole transport layer, HTL)FAPbBr₃器件里报道的最高值。

关键词: FAPbBr₃钙钛矿太阳能电池, TiO₂ / FAPbBr₃层, TEAOH, 两步旋涂, 界面修饰

Formamidinium lead bromide (FAPbBr₃) perovskite solar cells (PSCs) have attracted increasing attention for applications in tandem photovoltaics, semi-transparent devices, and photocatalysis owing to their wide bandgap, excellent thermal stability, and high open-circuit voltage. Compared with iodide-based perovskites, FAPbBr₃ exhibits superior resistance to moisture, heat, and phase instability. However, its relatively wide bandgap limits the short-circuit current density in single-junction devices, and severe interfacial defect-induced nonradiative recombination at the electron transport layer (ETL)/perovskite interface further constrains device performance, especially in hole-transport-layer-free (HTL-free) architectures.
In this work, high-quality FAPbBr₃ perovskite films were fabricated via a two-step solution spin-coating method, in which PbBr₂ films were first deposited followed by the spin-coating of a formamidinium bromide (FABr) methanol solution. To regulate interfacial charge transport and suppress defect-assisted recombination, tetraethylammonium hydroxide (TEAOH) was introduced as an interfacial modifier at the TiO₂/FAPbBr₃ interface. By systematically tuning the concentration of the TEAOH aqueous solution, the influence of interfacial modification on perovskite crystallization, defect passivation, and carrier dynamics was comprehensively investigated.
Morphological characterization by scanning electron microscopy revealed that an optimal TEAOH concentration of 4 mg·mL^-1 significantly improved the film quality, featuring enlarged grain size, reduced grain boundary density, and a more compact and uniform morphology. X-ray diffraction analysis confirmed enhanced crystallinity and improved phase purity of the FAPbBr₃ films after TEAOH modification. Meanwhile, ultraviolet-visible absorption spectra demonstrated strengthened light-harvesting capability, which can be attributed to the improved microstructure and reduced optical scattering losses.
Electrical and spectroscopic analyses, including steady-state and time-resolved photoluminescence, space-charge-limited current measurements, electrochemical impedance spectroscopy, and transient optoelectronic characterization, consistently revealed that TEAOH modification effectively reduced interfacial defect density, suppressed nonradiative recombination, and promoted faster electron extraction at the TiO₂/FAPbBr₃ interface. As a result, the optimized HTL-free FAPbBr₃ PSC delivered a high open-circuit voltage of 1.63 V, a short-circuit current density of 7.99 mA·cm^-2, and a fill factor of 83.74%, achieving a power conversion efficiency of 10.91%, which represents the highest reported efficiency for HTL-free FAPbBr₃-based PSCs to date. In addition, the modified devices exhibited stable current output under continuous illumination.
This study demonstrates that TEAOH interfacial engineering is a simple yet highly effective strategy to simultaneously improve crystallization quality, interfacial charge transport, and photovoltaic performance in wide-bandgap perovskite solar cells, offering valuable insights for the development of efficient and stable perovskite optoelectronic devices.

Key words: FAPbBr₃ perovskite solar cells, TiO₂/FAPbBr₃ interface, tetraethylammonium hydroxide, two-step spin-coating, interfacial modification

引用此文

汪佳艳, 郭焕焕, 殷逍遥, 张昀照, 王威, 赵晨瑞, 陈洁, 文洁, 孙伟海. TEAOH界面修饰制备高效FAPbBr₃钙钛矿太阳能电池[J]. 化学学报, doi: 10.6023/A25100347.

Wang Jiayan, GUO Huanhuan, Yin Xiaoyao, Zhang Yunzhao, Wang Wei, Zhao Chenrui, Chen Jie, Wen Jie, Sun Weihai. Preparation of High-Efficiency FAPbBr₃ Perovskite Solar Cells via TEAOH Interface Modification[J]. Acta Chimica Sinica, doi: 10.6023/A25100347.

导出引用 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

分享此文

参考文献

[1] Akkerman Q.A.; Manna, L. ACS Energy Lett.2020, 5,604.
[2] Li N.X.; Tao S.X.; Chen, Y.H; Niu X.X.; Onwudinanti C.K.; Hu C.; Qiu Z.W.; Xu Z.Q.; Zheng G.H.; Wang L.G.; Zhang Y.; Li L.; Liu H.F.; Lun Y.Z.; Hong J.W.; Wang X.Y.; Liu Y.Q.; Xie H.P.; Gao Y.L.; Bai Y.; Yang S.H.; Brocks G.; Chen Q.; Zhou H.P. Nat. Energy.2019, 4,408.
[3] Xu L.; Wu D.; Lv W.X.; Xiang Y.; Liu Y.; Tao Y.; Yin J.; Qian M.Y.; Li P.; Zhang L.Q.; Chen S.F.; Mohammed O.F.; Bakr O.M.; Duan Z.; Chen R.F.; Huang W. Adv. Mater.2022,34,2107111.
[4] Zou,Y.; Li,Z.; Chen,H.H.; Liu,Y.C.; Tong,A.L.; Yan,H.Y.; He,R.W.; Hua,G.X.; Zeng,W.D.; Sun,W.H. CHINESE JOURNAL OF LUMINESCENCE.2021,42,682.
(邹宇,李昭,陈衡慧,刘伊辰,童安玲,颜惠英,何若玮,花国鑫,曾伟东,孙伟海. 发光学报. 2021,42.682.)
[5] Wang H.; Zhang C.Q.;Huang W.Q.;Zou X.P.;Chen Z.Y.;Sun S.L.;Zhang L.X.;Li J.M.;Cheng J.;Huang S.X.;Gu M.K.;Chen X.Y.;Guo X.;Gui R.X.; Wang, W.M. Phys. Chem. Chem. Phys.2022,24,27585.
[6] Shaw B.K.;Castillo-Blas, C.;Thorne, M.F.;Ríos Gómez, M.L.;Forrest, T.;Lopez, M.D.;Chater, P.A.;McHugh, L.N.;Keen, D.A.; Bennett, T.D. Chem. Sci. 2022, 13,2033.
[7] Jeon N.J.;Noh J.H.;Kim Y.C.;Yang W.S.;Ryu S.; Seok S.I. Nat. Mater.2014, 13,897.
[8] Kieslich G.;Sun S.J.; Cheetham A.K. Chem. Sci.2015, 6,3430.
[9] Zhu J.W.;Tang M.X.;He B.L.;Zhang W.Y.;Li,X.K.; Gong,Z.K.; Chen,H.Y.; Duan,Y.Y.; Tang, Q.W. J. Mater. Chem. A.2020, 8,20987.
[10] Ti J.J.;Zhu J.W.;He B.L.;Zong Z.H.;Yao X.P.;Tui R.;Huang H.;Chen C.;Chen H.Y.;Duan Y.Y.; Tang, Q.W. J. Mater. Chem. A.2022,10,6649.
[11] Cui L.F.; He B.L.;Ding Y.; Zhu,J.W.; Yao,X.P.; Ti,J.J.; Chen,H.Y.; Duan,Y.Y.; Tang Q.W. Chem. Eng. J.2022,431,134193.
[12] Carulli F.;He M.D.;Cova F.;Erroi A.;Li L.;Brovelli, S. ACS Energy Lett.2023, 8,1795.
[13] Li,H.; Wang,Z.Y.; Zheng,S.Z.; Zhu,W.H.; Zhang,Y.Y.; Wang,Y.; Sun,W.H.; Wu,J.H.Surf. Interf. 2025,62,106255.
[14] Zhao Y.Y.;Wang Y.D.;Duan J.L.;Yang X.Y.; Tang, Q.W. J. Mater. Chem. A.2019, 7,6877.
[15] Eperon G.E.;Stranks S.D.;Menelaou C.;Johnston M.B.;Herz L.M.; Snaith, H.J. Energy Environ. Sci.2014, 7,982.
[16] Klug M.T.;Osherov A.;Haghighirad A.A.;Stranks S.D.;Brown P.R.;Bai S.;Wang J.T.W.;Dang X.N.;Bulovic V.;Snaith H.J.; Belcher, A.M. Energy Environ. Sci.2017, 10,236.
[17] Zheng,Q.S.;Cao,F.X.;Wang,Y.H.;Tong,A.L.;Wang,S.B.;Chen,P.X.;Zhao,Z.Y.;Wang,Y.;Sun,W.H.;Pan,W.C.;Li,Y.L.;Wu J.H. Inorg. Chem. Front.2024,11,6627.
[18] Das Adhikari R.;Baishya H.;Patel M.J.;Yadav D.; Iyer P.K. Small.2024, 20,2404588.
[19] Duan J.L.;Zhao Y.Y.;Wang Y.D.;Yang X.Y.; Tang, Q.W. Angew. Chem. Int. Ed.2019, 58,16147.
[20] Tu Y.G.;Xu G.N.;Yang X.Y.;Zhang Y.F.;Li Z.J.;Su R.;Luo D.Y.;Yang W.Q.;Miao Y.;Cai R.;Jiang L.H.;Du X.W.;Yang Y.C.;Liu Q.S.;Gao Y.;Zhao S.;Huang W.;Gong Q.H.; Zhu, R. Sci. China-Phys. Mech. Astron.2019, 62,974221.
[21] Zhu,W.H.; Wang,Y.J.; Li,H.; Wang,Y,; Zheng S.Z.; Wang,Z.Y.; Chen,S.T.; Sun,W.H.Acta Chim. Sinica.2025,83,616.
(朱文昊;汪玉杰;李浩;汪杨;郑松志;王则远;陈劭添;孙伟海. 化学学报.2025,83,616.)
[22] Dong Q.F.;Fang Y.J.;Shao Y.C.;Mulligan P.;Qiu J.;Cao L.; Huang J.S. Science.2015, 347,967.
[23] Shaw B.K.;Castillo-Blas, C.;Thorne, M.F.;Ríos Gómez, M.L.;Forrest, T.;Lopez, M.D.;Chater, P.A.;McHugh, L.N.;Keen, D.A.; Bennett, T.D.Chem. Sci. 2022, 13,2033.
[24] Li Y.R.;Zhang Y.;Zhu P.D.;Li J.B.;Wu J.W.;Zhang J.Y.;Zhou X.Y.;Jiang Z.Y.;Wang X.Z.; Xu, B.M. Adv. Funct. Mater.2023, 33,2309010.
[25] Tong,A.L.; Jin,Z.H.; Chen,X.H.; Zhu,W.H.; Zheng,Q.S.; Wang,Y.H.; Wang,Y.; Ma,N.G; Sun W.H.; Fu,C.P.; Wu,J.H.; Li Y.L. Chem. Eng. J.2025,503,158507.
[26] Yin,X.Y.;Zhu,W.H.; Shi,P.Y.; Li,Z.S.; Wang,Y.C.; Zhu,N.M.; Wang,Y.; Sun,W.H.Chin.J.Inorg.Chem. 2025,41,469.
(殷逍遥;朱文昊;施谱垚;李宗盛;王艺超;朱能敏;汪杨;孙伟海. 无机化学学报. 2025,41,469.)
[27] Wang X.;Zhang D.;Liu B.Z.;Wu X.;Jiang X.F.;Zhang S.F.;Wang Y.;Gao D.P.;Wang L.N.;Wang H.L.;Huang Z.M.;Xie X.F.;Chen T.;Xiao Z.G.;He Q.Y.;Xiao S.;Zhu Z.L.; Yang S.F. Adv. Mater.2023, 35,2305946.
[28] Amelenan Torimtubun A.A.;Mendez M.;Sanchez J.G.;Pallares J.;Palomares E.; Marsal, L.F. Sustain. Energ. Fuels.2021, 5,6498.
[29] Zheng,S.Z.; Li,H.; Wang,Z.Y.; Wang,Y.; Yin,C. Chen X.H.; Zhu,W.H.; Sun W.H. Chinese Science Bullwtin.2024,69,2814.
(郑松志;李浩;王则远;汪杨;阴聪;陈宣衡;朱文昊;孙伟海. 科学通报. 2024,69,2814.)
[30] Yan F.R.;Duan J.L.;Guo Q.Y.;Zhang Q.Y.;Yang X.Y.;Yang P.Z.; Tang, Q.W. Sci. China Mater.2023, 66,485.
[31] He J.C.;Sheng W.P.;Yang J.;Zhong Y.;Su Y.;Tan L.C.; Chen, Y.W. Energy Environ. Sci.2023, 16,629.
[32] He,R.W.; Wu,Y.J.; Li,Z.; Wang,Y.; Zhu,W.H.; Tong,A.L.; Chen,X.H.; Pan,W.C.; Sun,W.H.; Wu,J.H.Surf.Interf. 2024,48,104274.
[33] Tong,A.L.; Chen,X.H.; Wang,Y.; Wang,Y.H.; Zheng,Q.S.; He,R.W.; Jin,Z.H.; Sun,W.H.; Li,Y.L.;Wu,J.H.ACS Appl. Mater. Interfaces. 2024,16,50640.
[34] Xu,T.T,;Xu,J.C.;Yuan,L.H.;Xu,G.Y.;Zhang,C.;Zhang,R.P.;Huang,S.H.;Wu,X.X.;Zeng,G.X.;Li,Y.W.Chin. J. Chem. 2025,43,2219.
[35] Yue W.; Yang H.; Cai H. Y.; Xiong Y. M.; Zhou T.; Liu Y. J.; Zhao J.; Huang F. Z.; Chen Y. B.; Zhong J. Adv. Mater.2023, 35, 2301548.
[36] Jafarzadeh F.; Dong L.R.; Jang D.J.; Wagner M.; Koch G.; Qiu S.D.; Feroze S.; Cerrillo J.G.; Brabec C.J.; Carlo A. D.; Brunetti F.; Egelhaaf H.J.; Matteocci F. Sol. RRL.2024, 8, 2400530.
[37] Zhang Y. F.; Liang, Y. Q; Wang, Y. J.; Guo F.W.; Sun L.C.; Xu, D.S. ACS Energy Lett.2018, 3, 1808.
[38] Liu Y.W.; Kim B. J.; Wu H.;Boschloo G.; Johansson E. M J.; ACS Appl. Energy Mater.2021, 4, 9276.
[39] Arora N.; Dar M. I.; Mojtaba A.J.; Giordano Fabrizio.; Oellet N.; Jacopin G.; Friend R.H.; Zakeeruddin S. M.; Gratzel M.Nano Lett. 2016, 16, 7155.

TEAOH界面修饰制备高效FAPbBr₃钙钛矿太阳能电池

Preparation of High-Efficiency FAPbBr₃ Perovskite Solar Cells via TEAOH Interface Modification

PDF

补充材料

可视化

摘要/Abstract

引用此文

分享此文

参考文献

相关文章 5

编辑推荐

相关统计

本文评价

[1]	朱文昊, 汪玉杰, 李浩, 汪杨, 郑松志, 王则远, 陈劭添, 孙伟海, 赵小敏. 聚丙烯酸钠界面工程制备高效稳定的全无机CsPbBr₃钙钛矿太阳能电池[J]. 化学学报, 2025, 83(6): 616-623.
[2]	梁世硕, 康树森, 杨东, 胡建华. 锂金属负极界面修饰及其在硫化物全固态电池中的应用[J]. 化学学报, 2022, 80(9): 1264-1268.
[3]	郭镇域, 周欢萍. 钙钛矿组分和结构设计及其发光二极管器件性能研究进展[J]. 化学学报, 2021, 79(3): 223-237.
[4]	杨英, 林飞宇, 朱从潭, 陈甜, 马书鹏, 罗媛, 朱刘, 郭学益. 无机钙钛矿太阳能电池稳定性研究进展[J]. 化学学报, 2020, 78(3): 217-231.
[5]	裴娟, 郝彦忠, 吕海军, 孙宝, 李英品, 王尚鑫. 异质结界面修饰对TiO₂/P3HT杂化太阳电池光电性能的增强作用[J]. 化学学报, 2014, 72(12): 1245-1250.