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用于高效钙钛矿太阳能电池的无掺杂剂N,N'-联咔唑基空穴传输材料的开发

Development of Dopant-Free N,N'-Bicarbazole-Based Hole Transport Materials for Efficient Perovskite Solar Cells.

作者信息

Adnan Muhammad, Naz Hira, Hussain Muzammil, Irshad Zobia, Hussain Riaz, Darwish Hany W

机构信息

Graduate School of Energy Science and Technology, Chungnam National University, Daejeon 34134, Republic of Korea.

Department of Chemistry, University of Okara, Okara 56300, Pakistan.

出版信息

Int J Mol Sci. 2024 Dec 6;25(23):13117. doi: 10.3390/ijms252313117.

DOI:10.3390/ijms252313117
PMID:39684826
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11642623/
Abstract

Efficient and stable hole-transport material (HTM) is essential for enhancing the efficiency and stability of high-efficiency perovskite solar cells (PSCs). The commonly used HTMs such as spiro-OMeTAD need dopants to produce high efficiency, but those dopants degrade the perovskite film and cause instability. Therefore, the development of dopant-free N,N'-bicarbazole-based HTM is receiving huge attention for preparing stable, cost-effective, and efficient PSCs. Herein, we designed and proposed seven distinct small-molecule-based HTMs (B1-B7), which are synthesized and do not require dopants to fabricate efficient PSCs. To design this new series, we performed synergistic side-chain engineering on the synthetic reference molecule (B) by replacing two methylthio (-SCH3) terminal groups with a thiophene bridge and electron-withdrawing acceptor. The enhanced phase inversion geometry of the proposed molecules resulted in reduced energy gaps and better electrical, optical, and optoelectronic properties. Density functional theory (DFT) and time-dependent DFT simulations have been used to study the precise photo-physical and optoelectronic properties. We also looked into the effects of holes and electrons and the materials' structural and photovoltaic properties, including light harvesting energy, frontier molecular orbital, transition density matrix, density of states, electron density matrix, and natural population analysis. Electron density difference maps identify the interfacial charge transfer from the donor to the acceptor through the bridge, and natural population analysis measures the amount of charge on each portion of the donor, bridge, and acceptor, which most effectively represents the role of the end-capped moieties in facilitating charge transfer. Among these designed molecules, the B6 molecule has the greatest absorbance (λ of 444.93 nm in dichloromethane solvent) and a substantially shorter optical band gap of 3.93 eV. Furthermore, the charge transfer analysis reveals superior charge transfer with improved intrinsic characteristics. Furthermore, according to the photovoltaic analysis, the designed (B1-B7) HTMs have the potential to provide better fill factor and open-circuit voltages, which will ultimately increase the power conversion efficiency (PCE) of PSCs. Therefore, we recommend these molecules for the next-generation PSCs.

摘要

高效且稳定的空穴传输材料(HTM)对于提高高效钙钛矿太阳能电池(PSC)的效率和稳定性至关重要。常用的HTM如螺环-OMeTAD需要掺杂剂才能产生高效率,但这些掺杂剂会使钙钛矿薄膜降解并导致不稳定性。因此,开发无掺杂剂的基于N,N'-联咔唑的HTM在制备稳定、经济高效的PSC方面受到了极大关注。在此,我们设计并提出了七种不同的基于小分子的HTM(B1-B7),它们经过合成且制备高效PSC时无需掺杂剂。为了设计这个新系列,我们通过用噻吩桥和吸电子受体取代两个甲硫基(-SCH3)端基,对合成参考分子(B)进行了协同侧链工程。所提出分子增强的相反转几何结构导致能隙减小以及更好的电学、光学和光电性能。密度泛函理论(DFT)和含时DFT模拟已用于研究精确的光物理和光电性能。我们还研究了空穴和电子的影响以及材料的结构和光伏性能,包括光捕获能量、前沿分子轨道、跃迁密度矩阵、态密度、电子密度矩阵和自然布居分析。电子密度差图确定了通过桥从供体到受体的界面电荷转移,自然布居分析测量供体、桥和受体各部分的电荷量,这最有效地体现了封端部分在促进电荷转移中的作用。在这些设计的分子中,B6分子具有最大吸光度(在二氯甲烷溶剂中的λ为444.93 nm)和3.93 eV的显著更短光学带隙。此外,电荷转移分析揭示了具有改善的本征特性的优异电荷转移。此外,根据光伏分析,设计的(B1-B7)HTM有潜力提供更好的填充因子和开路电压,这最终将提高PSC的功率转换效率(PCE)。因此,我们推荐这些分子用于下一代PSC。

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