SIOC 中文
ACS
Adv search

Acta Chimica Sinica >

2024 , Vol. 82 >Issue 9: 987 - 1000

DOI: https://doi.org/10.6023/A24040134

Review

Recent Progress of Two-step Spin-coated Formamidinium Lead-based Perovskite Solar Cells

  • Yubo Chen ,
  • Dexu Zheng ,
  • Nan Wang ,
  • Jishuang Liu ,
  • Fengyang Yu ,
  • Sajian Wu ,
  • Shengzhong Liu ,
  • Zhipeng Li
Expand
  • a Dalian National Laboratory for Clean Energy, Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian 116023, Liaoning, China
    b CNNP Optoelectronics Technology (Shanghai) Co., Ltd., Shanghai 201306, China
    c Key Laboratory of Applied Surface and Colloid Chemistry, Ministry of Education, Shaanxi Key Laboratory for Advanced Energy Devices, Shaanxi Engineering Lab for Advanced Energy Technology, Institute for Advanced Energy Materials, School of Material: Science and Engineering, Shaanxi Normal University, Xi’an 710119, China
† These authors contributed equally to this work
*E-mail: ;
*E-mail: ;

Received date: 2024-04-29

  Online published: 2024-07-10

Supported by

National Key Research Program of China(2022YFE0138100); National Key Research Program of China(SQ2022YFE010083); National Nature Science Foundation of China(52350710208); Cooperation Foundation of Yulin University, and Dalian National Laboratory for Clean Energy(YLU-DNL fund 2022011)

Fold

Abstract

In recent years, perovskite solar cells (PSCs) have gained much attention due to their superior photoelectric conversion performance, and the photoelectric conversion efficiency (PCE) of the perovskite solar cells prepared in laboratories up to 26%. However, despite these advancements, the scaling-up process often leads to significant efficiency losses, which limits its further commercialization. It is crucial to develop an affordable, scalable, and controllable production method. The most commonly used preparation methods for perovskite films are the one-step method and the two-step method. Unfortunately, the one-step method suffers from a narrow processing window and environmental concerns as it requires the addition of an anti-solvent, which leads to poor reproducibility and hinders the scaling-up process. In contrast, the two-step method exhibits high reproducibility and friendliness to operators and the environment as perovskite films' growth is divided into two parts. In addition, the two-step spin coating solution method stands out for its easy fabrication, good repeatability, and high operability. It is conducive to the controllable preparation of high-quality large-area perovskite films and has great potential in commercial applications. Based on the characteristics that the preparation of perovskite is divided into two steps, the two-step solution method has more regulatory directions, and a lot of research work has been reported. In this review, the recent progress and the problems of the two-step spin coating solution method in additive engineering, interface modification, solvent engineering, and other engineering are described in detail, and the challenges and future research prospects of the two-step spin coating solution method are also analyzed. Additive engineering involves incorporating additives into inorganic components, organic components, and charge transport layers. Interface modification encompasses electron transport layer- perovskite interface as well as perovskite-hole transport layer interfaces. The purpose of this review is to provide insight into the research of large-area and high-performance perovskite solar cells.

Key words: perovskite; solar cells; two-step; spin-coating; photoelectric conversion efficiency

Cite this article

Yubo Chen , Dexu Zheng , Nan Wang , Jishuang Liu , Fengyang Yu , Sajian Wu , Shengzhong Liu , Zhipeng Li . Recent Progress of Two-step Spin-coated Formamidinium Lead-based Perovskite Solar Cells[J]. Acta Chimica Sinica, 2024 , 82(9) : 987 -1000 . DOI: 10.6023/A24040134

References

[1]
De Wolf-S.; Holovsky J.; Moon S.-J.; L?per P.; Niesen B.; Ledinsky M.; Haug F.-J.; Yum J.-H.; Ballif C. J. Phys. Chem. Lett. 2014, 5, 1035.
[2]
Lv S.-L.; Pang S.-P.; Zhou Y.-Y.; Padture N.-P.; Hu H.; Wang L.; Zhou X.-H.; Zhu H.-M.; Zhang L.-X.; Huang C.-S.; Cui G.-L. Phys. Chem. Chem. Phys. 2014, 16, 19206.
[3]
Miyata A.; Mitioglu A.; Plochocka P.; Portugall O.; Wang J.T.-W.; Stranks S.-D.; Snaith H.-J.; Nicholas R.-J. Nat. Phys. 2015, 11, 582.
[4]
Cai Y.; Cui J.; Chen M.; Zhang M.-M.; Han Y.; Qian F.; Zhao H.; Yang S.-M.; Yang Z.; Bian H.-T.; Wang T.; Guo K.-P.; Cai M.-L.; Dai S.-Y.; Liu Z.; Liu S.-Z. Adv. Funct. Mater. 2020, 31, 2005776.
[5]
Liu Y.-L.; Xiang W.-C.; Xu T.-F.; Zhang H.; Xu H.-J.; Zhang Y.-C.; Qi W.-Z.; Liu L.-D.; Yang T.-T.; Wang Z.-Z.; Liu S.-Z. Small 2023, 19, 2304190.
[6]
Yang L.; Feng J.-S.; Liu Z.-K.; Duan Y.-W.; Zhan S.; Yang S.-M.; He K.; Li Y.; Zhou Y.-W.; Yuan N.-Y.; Ding J.-N.; Liu S.-Z. Adv. Mater. 2022, 34, 2201681.
[7]
Ma S.-M.; Xue X.-Y.; Wang K.; Wen Q.; Han Y.-H.; Wang J.-Q.; Yao H.; Lu H.; Cui L.-H.; Ma J.-F.; Zhang L.; Liu L.; Zhang H.-X.; Farhadi B.; Wang K.; Liu S.-Z. Adv. Energy Mater. 2024, 14, 2303193.
[8]
Li Y.; Duan Y.-W.; Liu Z.-K.; Yang L.; Li H.-X.; Fan Q.-P.; Zhou H.; Sun Y.-Q.; Wu M.-Z.; Ren X.-D.; Yuan N.-Y.; Ding J.-N.; Yang S.-M.; Liu S.-Z. Adv. Mater. 2024, 36, 202310711.
[9]
Wei Q.; Cheng Y.; Gao Y.; Wang N.; Hou X.; Zan L.; Duan Y.; Fu F.; Yang D.; Liu S. Sol. RRL 2024, 8, 2300816.
[10]
Kojima A.; Teshima K.; Shirai Y.; Miyasaka T. J. Am. Chem. Soc. 2009, 131, 6050.
[11]
NREL. https://www.nrel.gov/pv/cell-efficiency.html
[12]
Saki Z.; Byranvand M.-M.; Taghavinia N.; Kedia M.; Saliba M. Energy Environ. Sci. 2021, 14, 5690.
[13]
Huang F.; Li M.-J.; Siffalovic P.; Cao G.-Z.; Tian J.-J. Energy Environ. Sci. 2019, 12, 518.
[14]
Jung M.; Ji S.-G.; Kim G.; Seok S.-I. Chem. Soc. Rev. 2019, 48, 2011.
[15]
Jeon N.-J.; Noh J.-H.; Kim Y.-C.; Yang W.-S.; Ryu S.; Seok S.-I. Nat. Mater. 2014, 13, 897.
[16]
Qin M.-C.; Xue H.-B.; Zhang H.-K.; Hu H.-L.; Liu K.; Li Y.-H.; Qin Z.-T.; Ma J.-J.; Zhu H.-P.; Yan K.-Y.; Fang G.-J.; Li G.; Jeng U.-S.; Brocks G.; Tao S.-X.; Lu X.-H. Adv. Mater. 2020, 32, 2004630.
[17]
Swartwout R.; Hoerantner M.-T.; Bulovi? V. Energy Environ. Mater. 2019, 2, 119.
[18]
Sun Q.; Duan S.-C.; Liu G.; Meng X.-X.; Hu D.; Deng J.-G.; Shen B.; Kang B.-N.; Silva S.R.-P. Adv. Energy Mater. 2023, 13, 2301259.
[19]
Chen H. Adv. Funct. Mater. 2017, 27, 1605654.
[20]
Kim S.-Y.; Jo H.-J.; Sung S.-J.; Kim D.-H. APL Mater. 2016, 4, 100901.
[21]
Han Y.-P.; Xie H.-B.; Lim E.-L.; Bi D.-Q. Sol. RRL 2022, 6, 2101007.
[22]
Wu Z.-F.; Bi E.-B.; Li C.-W.; Chen L.; Song Z.-N.; Yan Y.-F. Sol. RRL 2022, 7, 2200571.
[23]
Burschka J.; Pellet N.; Moon S.-J.; Humphry-Baker R.; Gao P.; Nazeeruddin M.-K.; Gr?tzel M. Nature 2013, 499, 316.
[24]
Zhang T.-Y.; Yang M.-J.; Zhao Y.-X.; Zhu K. Nano Lett. 2015, 15, 3959.
[25]
Yang W.-S.; Noh J.-H.; Jeon N.-J.; Kim Y.-C.; Ryu S.; Seo J.; Seok S.-I. Science 2015, 348, 1234.
[26]
Wu J.-H.; Xu X.; Zhao Y.-H.; Shi J.-J.; Xu Y.-Z.; Luo Y.-H.; Li D.; Wu H.-J.; Meng Q.-B. ACS Appl. Mater. Interfaces 2017, 9, 26937.
[27]
Zhao Y.-C.; Tan H.-R.; Yuan H.-F.; Yang Z.-Y.; Fan J.-Z.; Kim J.; Voznyy O.; Gong X.-W.; Quan L.-N.; Tan C.-S.; Hofkens J.; Yu D.-P.; Zhao Q.; Sargent E.-H. Nat. Commun. 2018, 9, 1607.
[28]
Hui W.; Chao L.-F.; Lu H.; Xia F.; Wei Q.; Su Z.-H.; Niu T.-T.; Tao L.; Du B.; Li D.; Wang Y.; Dong H.; Zuo S.; Li B.-X.; Shi W.; Ran X.-Q.; Li P.; Zhang H.; Wu Z.-B.; Ran C.-X.; Song L.; Xing G.-C.; Gao X.-Y.; Zhang J.; Xia Y.-D.; Chen Y.-H.; Huang W. Science 2021, 371, 1359.
[29]
Zhao Y.; Ma F.; Qu Z.-H.; Yu S.-Q.; Shen T.; Deng H.-X.; Chu X.-B.; Peng X.-X.; Yuan Y.-B.; Zhang X.-W.; You J.-B. Science 2022, 377, 531.
[30]
Jiang Q.; Chu Z.-M.; Wang P.-Y.; Yang X.-L.; Liu H.; Wang Y.; Yin Z.-G.; Wu J.-L.; Zhang X.-W.; You J.-B. Adv. Mater. 2017, 29, 1703852.
[31]
Chauhan M.; Zhong Y.; Sch?tz K.; Tripathi B.; K?hler A.; Huettner S.; Panzer F. J. Mater. Chem. A 2020, 8, 5086.
[32]
Wu Y.-Z.; Islam A.; Yang X.-D.; Qin C.-J.; Liu J.; Zhang K.; Peng W.-Q.; Han L.-Y. Energy Environ. Sci. 2014, 7, 2934.
[33]
Zhao Y.; Zhang X.; Han X.-F.; Hou C.-Y.; Wang H.-Z.; Qi J.-B.; Li Y.-G.; Zhang Q.-H. Chem. Eng. J. 2021, 417, 127912.
[34]
Gao Y.; Raza H.; Zhang Z.-P.; Chen W.; Liu Z.-H. Adv. Funct. Mater. 2023, 33, 2215171.
[35]
Zhou S.-H.; Zhang W.-F.; Jiang Y.-T.; Lin P.-A.; Zhou X.-Q.; Huang Y.-L. Acta Energ. Sol. Sin. 2022, 43, 78 (in Chinese).
[35]
(周生厚, 章文峰, 江雨童, 林埔安, 周祥青, 黄跃龙, 太阳能学报, 2022, 43, 78.)
[36]
Bai D.-L.; Zheng D.-X.; Yang S.-A.; Yu F.-Y.; Zhu X.-J.; Peng L.; Wang L.-K.; Liu J.-S.; Yang D.; Liu S.-Z. RSC Adv. 2023, 13, 28097.
[37]
Bai D.-L.; Zheng D.-X.; Yang S.-A.; Peng L.; Wang P.-J.; Liu J.-S.; Zhu X.-J.; Yang D.; Liu S.-Z.F. Sol. RRL 2024, 8, 2301036.
[38]
Zhang H.; Xu Z.-P.; Zhu C.-T.; Guo X.-Y.; Yang Y. J. Inorg. Mater. 2024, 39, 457 (in Chinese).
[38]
(张慧, 许志鹏, 朱从潭, 郭学益, 杨英, 无机材料学报, 2024, 39, 457.)
[39]
He J.-C.; Sheng W.-P.; Yang J.; Zhong Y.; Su Y.; Tan L.-C.; Chen Y.-W. Energy Environ. Sci. 2023, 16, 629.
[40]
Du Y.-T.; Wang Y.; Wu J.-H.; Chen Q.; Deng C.-Y.; Ji R.; Sun L.-X.; Tan L.-N.; Chen X.; Xie Y.-M.; Huang Y.-F.; Vaynzof Y.; Gao P.; Sun W.-H.; Lan Z. InfoMat. 2023, 5, e12431
[41]
Zeng G.-Y.; Liu G.-Y.; Li X. ACS Sustainable Chem. Eng. 2023, 11, 7664.
[42]
Liang X.; Zhou K.; Duan D.-W.; Wang F.; Ge C.-Y.; Zhou X.-F.; Yuan M.-J.; Shi Y.-M.; Lin H.-R.; Zhu Q.-Y.; Li G.; Hu H.-L. Chem. Eng. J. 2023, 459, 141524.
[43]
Li X.-D.; Zou Y.; Yu S.-B.; Zhao X.; Yu W.-J.; Yang S.; Guo H.-Q.; Xiao L.-X.; Chen Z.-J.; Qu B. Sol. RRL 2023, 7, 2300091.
[44]
Zhang Y.; Park N. G. Adv. Funct. Mater. 2023, 33, 2308577.
[45]
Zhang Y.-L.; Yang T.-H.; Lee S.-U.; Liu S.-Z.; Zhao K.; Park N.-G. ACS Energy Lett. 2023, 9, 159.
[46]
Guo Z.-H.; Chen W.-X.; Wang H.-X.; Cai W.-S.; Qaid S.M.H.; Zang Z.-G. Inorg. Chem. 2023, 62, 14086.
[47]
Liang X.; Duan D.-W.; Al-Handawi M.-B.; Wang F.; Zhou X.-F.; Ge C.-Y.; Lin H.-R.; Zhu Q.-Y.; Li L.; Naumov P.; Hu H.-L. Sol. RRL 2022, 7, 2200856.
[48]
Sun Y.-G.; Hu R.-Y.; Wang F.; Wang T.-M.; Liang X.; Zhou X.-F.; Yang G.; Li Y.-J.; Zhang F.; Zhu Q.-Y.; Li X.-A.; Hu H.-L. J. Mater. Chem. C 2024, 12, 5175.
[49]
Liu C.-C.; Su H.-J.; Pu Y.; Guo M.; Zhai P.; Liu Z.-K.; Zhang Z. Nano Energy 2023, 118, 108990.
[50]
Wu X.-X.; Xu G.-Y.; Yang F.; Chen W.-J.; Yang H.-Y.; Shen Y.-X.; Wu Y.-Y.; Chen H.-Y.; Xi J.-C.; Tang X.-H.; Cheng Q.-R.; Chen Y.-J.; Ou X.-M.; Li Y.-W.; Li Y.-F. ACS Energy Lett. 2023, 8, 3750.
[51]
Wang Y.-P.; Xiao Y.-M.; Wang L.-D.; Su Z.-S.; Xu Y.-P.; Fan L.-B.; Yao G.-P.; Qian X.; Lin J.-Y. J. Power Sources 2024, 602, 234383.
[52]
Ahn S.; Chiu W.-H.; Cheng H.-M.; Suryanarayanan V.; Chen G.; Huang Y.-C.; Wu M.-C.; Lee K.-M. Org. Electron. 2023, 120, 106847.
[53]
Hou M.-N.; Guo X.; Han M.-D.-X.; Zhao J.-T.; Wang Z.-Y.; Ding Y.; Hou G.-F.; Zhang Z.-S.; Han X.-P. Chin. Phys. B 2024, 33, 047802.
[54]
Sun D.-R.; Gao Y.; Raza H.; Liu S.-W.; Ren F.-M.; Hu X.-D.; Wang H.-X.; Meng X.; Wang J.-N.; Chen R.; Sun H.-D.; He J.; Zhou J.; Pan Y.-Y.; Sun Z.-X.; Chen W.; Liu Z.-H. Adv. Funct. Mater. 2023, 33, 2303225.
[55]
Ren N.-Y.; Wang P. - Y.; Jiang J.-K.; Li R.-J.; Han W.; Liu J.-J.; Zhu Z.; Chen B.-B.; Xu Q.-J.; Li T.-T.; Shi B.; Huang Q.; Zhang D.-K.; Apergi S.; Brocks G.; Zhu C.-J.; Tao S.-X.; Zhao Y.; Zhang X.-D. Adv. Mater. 2023, 35, 2211806.
[56]
Yang H.-M.; Hao Y.; Ren J.-K.; Wu Y.-K.; Sun Q.-J.; Zhang C.-X.; Cui Y.-X.; Hao Y.-Y. J. Mater. Chem. C 2023, 11, 8470.
[57]
Wu T.; Ji W.-X.; Zhang L.-G.; Chen Q.-Y.; Fu J.-F.; Zhang J.-J.; Zhang Z.-L.; Zhou Y.; Dong B.; Song B. J. Mater. Chem. A 2023, 11, 3599.
[58]
Shao C.; He J.-D.; Niu G.-S.; Dong Y.; Yang K.-Y.; Cao X.-F.; Wang J.-Z.; Yang H.-X. Small 2023, 2309009.
[59]
Zhang D.; Wang X.-F.; Fan Z.-P.; Zhao Y.-X.; Xia X.-F.; Li F. ACS Appl. Mater. Interfaces 2024, 16, 12833.
[60]
Wang Y.-F.; Yuan S.-H.; Feng R.-S.; Diao Z.-C.; Huang J.; Liao J.-C.; Sidhik S.; Shuai X.-T.; Wang M.-C.; Zou T.; Liang Z.-W.; Zhang T.; Mohite A.-D.; Li S.-B. APL Mater. 2024, 12, 031128.
[61]
Yu R.-N.; Wu G.-Z.; Shi R.; Ma Z.-W.; Dang Q.; Qing Y.-Z.; Zhang C.-Y.; Xu K.-X.; Tan Z.-A. Adv. Energy Mater. 2022, 13, 2203127.
[62]
Shao W.-L.; Wang H.-B.; Ye F.-H.; Wang C.; Wang C.; Cui H.-S.; Dong K.-L.; Ge Y.-S.; Wang T.; Ke W.-J.; Fang G.-J. Energy Environ. Sci. 2023, 16, 252.
[63]
He J.-C.; Sheng W.-P.; Yang J.; Zhong Y.; Cai Q.-Q.; Liu Y.-K.; Guo Z.; Tan L.-C.; Chen Y.-W. Angew. Chem., Int. Ed. 2023, 63, e202315233
[64]
Yan L.-Y.; Huang H.; Cui P.; Du S.-X.; Lan Z.-N.; Yang Y.-Y.; Qu S.-J.; Wang X.-X.; Zhang Q.; Liu B.-Y.; Yue X.-P.; Zhao X.; Li Y.-F.; Li H.-F.; Ji J.; Li M.-C. Nat. Energy. 2023, 8, 1158.
[65]
Wu Y.-Y.; Xu G.-Y.; Xi J.-C.; Shen Y.-X.; Wu X.-X.; Tang X.-H.; Ding J.-Y.; Yang H.-Y.; Cheng Q.-R.; Chen Z.-Y.; Li Y.-W.; Li Y.-F. Joule 2023, 7, 398.
[66]
Li M.-H.; Zhou J.-J.; Tan L.-G.; Li H.; Liu Y.; Jiang C.-F.; Ye Y.-R.; Ding L.-M.; Tress W.; Yi C.-Y. The Innovation. 2022, 3, 100310.
[67]
Liu C.-C.; Su H.-J.; Pu Y.; Guo M.; Zhai P.; Liu L.; Fu H.-Z. Adv. Funct. Mater. 2023, 33, 2212577.
[68]
Yan G.-Y.; Ma Z.; Yu L.; Ge H.; Huang Y.-L. Chem. Eng. Des. Commun. 2024, 50, 7 (in Chinese).
[68]
(晏广元, 马柱, 余朗, 葛浩, 黄跃龙, 化工设计通讯, 2024, 50, 7.)
[69]
Xu Y.-B.; Wang S.-R.; Liu H.-L.; Li X.-G. Adv. Mater. 2024, e2313080.
[70]
Tu Y.-B.; Li G.-D.; Ye J.-C.; Deng C.-Y.; Liu R.-C.; Yang G.-Y.; Shao T.-X.; Li Y.; Zang Y.; Wang Y.; Zhou Q.; Wu J.-H.; Yan W.-S. Small 2023, e2309033.
[71]
Jiao B.-X.; Ye Y.-R.; Tan L.-G.; Liu Y.; Ren N.-Y.; Li M.-H.; Zhou J.-J.; Li H.; Chen Y.; Li X.-Y.; Yi C.-Y. Adv. Mater. 2024, 2313673.
[72]
Wang S.-H.; Luo H.-Q.; Gu Z.-K.; Zhao R.-D.; Guo L.-T.; Wang N.; Lou Y.-J.; Xu Q.; Peng S.; Zhang Y.-Q.; Song Y.-L. Adv. Funct. Mater. 2023, 33, 2214834.
[73]
Tuo B.-Y.; Wang Z.-Y.; Ren Z.-Q.; Zhang H.-W.; Lu X.-Q.; Zhang Y.-Q.; Zang S.-Q.; Song Y.-L. Energy Environ. Sci. 2024, 17, 2945.
[74]
Lee H.-B.; Kumar N.; Cho S.; Hong S.; Lee H.-H.; Kim H.-J.; Lee J.-S.; Kang J.-W. Adv. Energy Sustainability Res. 2022, 4, 2200128.
[75]
Dastan D.; Mohammed K.A.-M.; Alnayli Sh.-R.; Majeed S.-M..; Ahmed S.-D.; Al-Mousoi K.-A.; Pandey R.; Hossain L.-M.; Bhattarai S.; Al-Asbahi A.-B.; Rahman F.-M. Langmuir 2024, 40, 7560.
[76]
Qin L.-N.; Zhu M.-F.; Xia Y.-R.; Ma X.-K.; Hong D.-C.; Tian Y.-X.; Tie Z.-X.; Jin Z. Nano Res. 2024, 17, 5131.
[77]
Wang H.-H.; Zhang Z.; Wang X.-B.; Duan L.-R.; Luo J.-S. Nano Energy 2024, 109423.
[78]
Yang W.-G.; Xiong X.-L.; Li Z.-P.; Liu X.; Wei X.-S.; Sun Z.-B.; Huang L.; Wang L.-J. Opt. Mater. 2023, 139, 113781.
[79]
Xu Y.-T.; Wang X.-J.; Jin Z.-M.; Li B.; An W.; Zhang Q.-H.; Rui Y.-C. Sol. RRL 2023, 7, 2300302.
[80]
Shi P.-J.; Ding Y.; Ding B.; Xing Q.-Y.; Kodalle T.; Sutter-Fella C.-M.; Yavuz I.; Yao C.-L.; Fan W.; Xu J.-Z.; Tian Y.; Gu D.-Y.; Zhao K.; Tan S.; Zhang X.; Yao L.-B.; Dyson P.-J.; Slack J.-L.; Yang D.; Xue J.-J.; Nazeeruddin M.-K.; Yang Y.; Wang R. Nature 2023, 620, 323.
[81]
Huang Z.-F.; Ma Z.; Deng C.; Yu T.-J.; Li G.-M.; Du Z.-W.; You W.; Yang J.-B.; Chen Y.; Li Y.-L.; Hou S.-Y.; Yang Q.; Zhang Q.; Du H.; Li Y.-X.; Shu H.; Liu Q.-Y.; Peng C.-T.; Huang Y.-L.; Yu J.; Lin Y.-H.; Sun K.; Long W. Adv. Energy Mater. 2023, 14, 2302769.
[82]
Huang Z.; Bai Y.; Huang X.; Li J.; Wu Y.; Chen Y.; Li K.; Niu X.; Li N.; Liu G.; Zhang Y.; Zai H.; Chen Q.; Lei T.; Wang L.; Zhou H. Nature 2023, 623, 531.
[83]
Finkenauer B.-P.; Zhang Y.; Ma K.; Turnley J.-W.; Schulz J.; Gómez M.; Coffey A.-H.; Sun D.; Sun J.; Agrawal R.; Huang L.; Dou L. J. Phys. Chem. C 2023, 127, 930.
[84]
Lin S.-Y.; Wu S.-Y.; Guo D.-e.; Huang H.; Zhou X.-F.; Zhang D.; Zhou K.-C.; Zhang W.-H.; Hu Y.; Gao Y.-L.; Zhou C.-H. Small Methods 2023, 7, 2201663.
[85]
Li S.-W.; Xia J.-M.; Wen Z.-R.; Gu H.; Guo J.; Liang C.; Pan H.; Wang X.-Z.; Chen S. Adv. Sci. 2023, 10, 2300056.
[86]
Wang F.; Zhou K.; Liang X.; Zhou X.-F.; Duan D.-W.; Ge C.-Y.; Zhang X.-T.; Shi Y.-M.; Lin H.-R.; Zhu Q.-Y.; Li L.; Hu H.-L.; Zhang H.-Y. Small Methods 2023, 8, 2300210.
[87]
Huang Y.-M.; Zhou W.-C.; Zhong H.-Y.; Chen W.; Yu G.-P.; Zhang W.-J.; Wang S.-L.; Sui Y.-J.; Yang X.; Zhuang Y.; Tang J.; Cao L.-F.; Müller-Buschbaum P.; Aierken A.; Han P.-G.; Tang Z.-G. Mater. Today Adv. 2024, 21, 100449.
[88]
Tian C.-M.; Wu T.-H.; Zhao Y.; Zhou X.-L.; Li B.; Han X.-F.; Li K.-R.; Hou C.-Y.; Li Y.-G.; Wang H.-Z.; Zhang Q.-H. Adv. Energy Mater. 2024, 14, 2303666.
[89]
Hoang Huy V. P.; Bark C. W. Polymers 2024, 16, 199.
[90]
Cheng N.; Li W.-W.; Zheng D.-S.; Yang W.-X. ChemPhotoChem 2024, e202300275.
[91]
Ji X.-F.; Bi L.-Y.; Fu Q.; Li B.-L.; Wang J.-W.; Jeong S.-Y.; Feng K.; Ma S.-X.; Liao Q.-G.; Lin F.-R.; Woo H.-Y.; Lu L.-F.; Jen K.-Y.-A.; Guo X.-G. Adv. Mater. 2023, 35, 2303665.
[92]
Gao Y.; Ren F.; Sun D.; Li S.; Zheng G.; Wang J.; Raza H.; Chen R.; Wang H.; Liu S.; Yu P.; Meng X.; He J.; Zhou J.; Hu X.; Zhang Z.; Qiu L.; Chen W.; Liu Z. Energy Environ. Sci. 2023, 16, 2295.
[93]
Wang S.-B.; Cao F.-X.; Chen P.; He R.-W.; Tong A.-L.; Lan Z.; Gao P.; Sun W.-H.; Wu J.-H. Chem. Eng. J. 2023, 453, 139721.
[94]
Li W.-Q.; Ding S.; Wu C.-Y.; Qian L.; Xiang C.-Y. Adv. Sustainable Syst. 2023, 7, 2300124.
[95]
Wang J.; Wang Z.-Y.; Chen S.-M.; Jiang N.; Yuan L.; Zhang J.; Duan Y. Sol. RRL 2023, 7, 2200960.
[96]
Sheng W.-P.; He J.-C.; Yang J.; Cai Q.-Q.; Xiao S.-Q.; Zhong Y.; Tan L.-C.; Chen Y.-W. Adv. Mater. 2023, 35, 2301852.
[97]
Qin Z.-X.; Chen Y.-T.; Wang X.-T.; Wei N.; Liu X.-M.; Chen H.-R.; Miao Y.-F.; Zhao Y.-X. Adv. Mater. 2022, 34, 2203143.
[98]
Gong C.; Zhang C.; Zhuang Q.-X.; Li H.-Y.; Yang H.; Chen J.-Z.; Zang Z.-G. Nano-Micro Lett. 2022, 15, 17.
[99]
Zhang X.-C.; Zhou Y.; Chen M.-Y.; Wang D.-X.; Chao L.-F.; Lv Y.-F.; Zhang H.; Xia Y.-D.; Li M.-J.; Hu Z.-L.; Chen Y.-H. Small 2023, 19, 2303254.
[100]
Zhang L.-H.; Fu C.; Wang S.; Wang M.-H.; Wang R.-T.; Xiang S.-L.; Wang Z.-Y.; Liu J.; Ma H.-R.; Wang Y.-D.; Yan Y.; Chen M.; Shi L.; Dong Q.-S.; Bian J.-M.; Shi Y.-T. Adv. Funct. Mater. 2023, 33, 2213961.
[101]
Zhai Z.-H.; Zhao Y.; Ma F.; You J.-B. Acta Phys. Sin. 2024, 73, 098802 (in Chinese).
[101]
(瞿子涵, 赵洋, 马飞, 游经碧, 物理学报, 2024, 73, 098802.)
[102]
Ren N.-Y.; Tan L.-G.; Li M.-H.; Zhou J.-J.; Ye Y.-R.; Jiao B.-X.; Ding L.-M.; Yi C.-Y. iEnergy 2024, 3, 39.
[103]
Wang J.; Wang K.-X.; Zhang C.-H.; Liu S.; Guan X.; Liang C.-J.; Chen C.-C.; Xie F.-X. Adv. Energy Mater. 2023, 13, 2302169.
[104]
Zhu C.; Wang X.; Li H.-X.; Wang C.-Y.; Gao Z.-Y.; Zhang P.-X.; Niu X.-X.; Li N.-X.; Xu Z.-P.; Su Z.-H.; Chen Y.-H.; Zai H.-C.; Xie H.-P.; Zhao Y.-Z.; Yang N.; Liu G.-L.; Wang X.-Y.; Zhou H.-P.; Hong J.-W.; Gao X.-Y.; Bai Y.; Chen Q. Interdiscip. Mater. 2023, 2, 348.
[105]
Song P.-Q.; Hou E.-L.; Liang Y.-M.; Luo J.-F.; Xie L.-Q.; Qiu J.-H.; Tian C.-B.; Wei Z.-H. Adv. Funct. Mater. 2023, 33, 2303841.
[106]
Qian J.-J.; He J.-J.; Zhang Q.-H.; Zhu C.-Y.; Chen S.-L.; Wei Z.-P.; Leng X.-S.; Zhou Z.-R.; Shen B.-B.; Peng Y.; Niu Q.; Yang S.; Hou Y. J. Energy Chem. 2024, 90, 496.
[107]
Li M.-H.; Zhou J.-J.; Tan L.-G.; Liu Y.; Wang S.-Y.; Jiang C.-F.; Li H.; Zhao X.; Gao X.-Y.; Tress W.; Ding L.-M.; Yi C.-Y. Energy Environ. Mater. 2022, 6, e12360
[108]
Zhang Y.; Song Q.; Liu G.; Chen Y.; Guo Z.; Li N.; Niu X.; Qiu Z.; Zhou W.; Huang Z.; Zhu C.; Zai H.; Ma S.; Bai Y.; Chen Q.; Huang W.; Zhao Q.; Zhou H. Nat. Photonics 2023, 17, 1066.
[109]
Aung K.K.-S.; Vijayan A.; Karimipour M.; Seetawan T.; Boschloo G. Electrochim. Acta 2023, 443, 141935.
[110]
Ye F.; Tian T.; Su J. ; Jiang R.-X.; Li J.; Jin C.-K.; Tong J.-H.; Bai S.; Huang F.-Z.; Müller‐Buschbaum P.; Cheng Y.-B.; Bu T.-L. Adv. Energy Mater. 2023, 14, 2302775.
[111]
Yue X.-P.; Zhao X.; Fan B.-B.; Yang Y.-Y.; Yan L.-Y.; Qu S.-J.; Huang H.; Zhang Q.; Yan H.-L.; Cui P.; Ji J.; Ma J.-F.; Li M.-C. Adv. Funct. Mater. 2022, 33, 2209921.
[112]
Li Y.; Gao F.; Luo C.; Wang X.-J.; Zhan C.-L.; Chen C.-P.; Zhao Q. Small 2024, 20, e2305956
[113]
Sun Q.; Meng X.; Deng J.; Shen B.; Hu D.; Kang B.; Silva S.R.-P. J. Alloys Compd. 2023, 959, 170478.
[114]
Qiu F.-Z.; Liu Q.-J.; Liu Y.-F.; Wu J.-P. Small 2023, 19, 2304834.
[115]
Ma Y.; Song Q.-Z.; Yang X.-Y.; Zai H.-C.; Yuan G.-Z.; Zhou W.-T.; Chen Y.-H.; Pei F.-T.; Kang J.-Q.; Wang H.; Song T.-L.; Wang X.-Y.; Zhou H.-P.; Li Y.-J.; Bai Y.; Chen Q. Nano Energy 2023, 108, 108250.
[116]
Sun Y.-P.; Zhang J.-K.; Yu B.; Shi S.-W.; Yu H.-Z. Nano Energy 2024, 121, 109245.
[117]
Ren G.-H.; Zhang Z.-G.; Deng Y.-Y.; Li Z.-W.; Liu C.-Y.; Wang M.-K.; Guo W.-B. Energy Environ. Sci. 2023, 16, 565.
[118]
Ma Y.-Y.; Zeng C.-S.; Zeng P.; Hu Y.-C.; Li F.-M.; Zheng Z.-H.; Qin M.-C.; Lu X.-H.; Liu M.-Z. Adv. Sci. 2023, 10, 2205072.
[119]
Xiao L.-B.; Xu X.-L.; Lu Z.; Zhao J.; Liu R.-Y.; Ye Y.-Q.; Tang R.-J.; Liao W.-Q.; Xiong R.-G.; Zou G.-F. Nano Energy 2023, 107, 108114.
[120]
Cai W.-X.; Wang Y.-D.; Li W.-Z.; Yin Y.-F.; Liu J.; Cai W.-Q.; Wang S.-H.; Guo J.-Y.; Chang S.; Li S.-K.; Wang X.-Y.; Shi Y.-T. Adv. Energy Mater. 2024, 2304521.
[121]
Zhang D.; Wang X.-F.; Tian T.-F.; Xia X.-F.; Duan J.-Y.; Fan Z.-P.; Li F. Chem. Eng. J. 2023, 469, 143789.
[122]
Chen P.; Xiao Y.; Li L.; Zhao L.-C.; Yu M.-T.; Li S.-D.; Hu J.-T.; Liu B.; Yang Y.-G.; Luo D.-Y.; Hou C.-H.; Guo X.-G.; Shyue J.-J.; Lu Z.-H.; Gong Q.-H.; Snait H.-J.; Zhu R. Adv. Mater. 2022, 35, 2206345.
[123]
Ma K.; Sun J.-N.; Atapattu H.-R.; Larson B.-W.; Yang H.-J.; Sun D.-W.; Chen K.; Wang K.; Lee Y.; Tang Y.-H.; Bhoopalam A.; Huang L.-B.; Graham K.-R.; Mei J.-G.; Dou L.-T. Sci. Adv. 2023, 9, eadg0032
[124]
Shen L.-N.; Song P.-Q.; Zheng L.-F.; Wang L.-P.; Zhang X.-G.; Liu K.-K.; Liang Y.-M.; Tian W.-J.; Luo Y.-J.; Qiu J.-H.; Tian C.-B.; Xie L.-Q.; Wei Z.-H. Adv. Mater. 2023, 35, 2301624.
[125]
Fan R.-D.; Song Q.-Z.; Huang Z.-J.; Ma Y.; Xiao M.-Q.; Huang X.-D.; Zai H.-C.; Kang J.-Q.; Xie H.-P.; Gao Y.-L.; Wang L.-N.; Zhang Y.; Wang L.; Wang F.; Zhang X.; Zhou W.-T.; Li N.-X.; Wang X.-Y.; Bai Y.; Liu G.-L.; Chen Q.; Wang L.-F.; Zhou H.-P. Angew. Chem., Int. Ed. 2023, 62, e202303176
[126]
Cheng N.; Yu Z.; Li W.-W.; Lei B.; Zi W.; Xiao Z.-Y.; Zhao Z.-Q.; Zong P.-A. Sol. Energy Mater. Sol. Cells 2023, 250, 112107.
[127]
Nie J.-H.; Zhang Y.-M.; Li L.-J.; Zhang Y. Adv. Devices Instrum. 2023, 4, 0025.
[128]
Zeng Q.; Ma Q.-M.; Li L.-H.; Zheng B.-L.; Pan Y.-N.; Zhao X.-Y.; Xiao H.-R.; Yan C.; Liu F.-Y. Chem. Commun. 2023, 59, 5269.
[129]
Li T.-H.; Xiong Q.; Hu C.-Z.; Wang C.; Zhang N.; Lien S.-Y.; Gao P. Molecules 2023, 28, 4103.
[130]
Cheng N.; Liu Z.; Li W.-W.; Yu Z.; Lei B.; Zi W.; Xiao Z.-Y.; Sun S.-J.; Zhao Z.-Q.; Zong P.-A. Chem. Eng. J. 2023, 454, 140146.
Options
Outlines

/