Low-Bandgap DPP-Based Quinoxaline with Extended EQE and Low Energy Loss for Efficient Polymer Solar Cells

Shah Muhammad Naeem; Yang Yatao; Sohail Muhammad; Pathipati Srinivasa Rao; Pan Xiaofang

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Low-Bandgap DPP-Based Quinoxaline with Extended EQE and Low Energy Loss for Efficient Polymer Solar Cells

机译：基于低带隙DPP的喹喔啉，具有延长的EQE和高能量损耗，高效的高分子太阳能电池

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摘要

In this study, we have designed and synthesized a low-bandgap polymer, DPP-Qx, using quinoxaline (Qx), a non-alkylated weak acceptor, with diketopyrrolopyrrole (DPP) as an electron donor. The incorporation of Qx into DPP leads to the highest occupied molecular orbital level at -5.1 eV with a narrow optical bandgap (1.25 eV). The synthesized polymer is utilized in photovoltaics, and the photovoltaic properties are studied. This DPP-Qx with fullerene acceptors in polymer solar cells (PSCs) exhibits efficiency of 3.26%. Moreover, a minimum energy loss of 0.57 eV along with high extended external quantum efficiency is achieved with the DPP-Qx electron donor. The thermal, electrical and optical properties, energy levels and hole mobility of the synthesized polymer are studied and discussed.

机译：在这项研究中，我们设计并合成了一种低带隙聚合物DPP Qx，使用非烷基化弱受体喹恶啉（Qx），以二酮吡咯（DPP）为电子供体。将Qx掺入DPP后，在-5.1ev的光禁带（1.25ev）范围内获得了最高的占据分子轨道能级。将合成的聚合物用于光伏发电，并对其光伏性能进行了研究。这种在聚合物太阳能电池（PSC）中含有富勒烯受体的DPP Qx的效率为3.26%。此外，DPP Qx电子给体的最小能量损失为0.57 eV，并具有较高的扩展外量子效率。对合成聚合物的热学、电学和光学性质、能级和空穴迁移率进行了研究和讨论。

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来源
《Journal of Electronic Materials》 |2021年第8期|共9页
作者
Shah Muhammad Naeem; Yang Yatao; Sohail Muhammad; Pathipati Srinivasa Rao; Pan Xiaofang;
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作者单位

Shenzhen Univ Dept Informat Engn Shenzhen Guangdong Peoples R China;

Shenzhen Univ Dept Informat Engn Shenzhen Guangdong Peoples R China;

Shenzhen Univ Dept Informat Engn Shenzhen Guangdong Peoples R China;

Vignans Fdn Sci Technol &

Res Div Phys Dept Sci &

Humanities Vadlamudi Andhra Pradesh India;

Shenzhen Univ Dept Informat Engn Shenzhen Guangdong Peoples R China;

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原文格式 PDF
正文语种 eng
中图分类计量学;材料;
关键词
Polymer solar cells; low voltage loss; quinoxaline; diketopyrrolopyrrole; low bandgap; wide absorption; electron-withdrawing;

机译：聚合物太阳能电池;低电压损失;喹喔啉;二酮吡咯;低带隙;宽吸收;电子提取;

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1. Low-bandgap polymers with quinoid unit as π bridge for high-performance solar cells [J] . Bilal Shahid, Xiyue Yuan, Qian Wang, 能源化学：英文版 . 2020,第001期
2. Low-bandgap polymers with quinoid unit as π bridge for high-performance solar cells [J] . Bilal Shahid, Xiyue Yuan, Qian Wang, 天然气化学（英文版） . 2020,第001期
3. Enhanced device performance of polymer solar cells by planarization of quinoxaline derivative in a low-bandgap polymer [J] . Yoonkyoo Lee, Young Min Nam, Won Ho Jo Journal of Materials Chemistry: An Interdisciplinary Journal dealing with Synthesis, Structures, Properties and Applications of Materials, Particulary Those Associated with Advanced Technology . 2011,第24期

机译：通过低带隙聚合物中喹喔啉衍生物的平面化提高聚合物太阳能电池的器件性能
4. Over 14% efficiency all-polymer solar cells enabled by a low bandgap polymer acceptor with low energy loss and efficient charge separation [J] . Fan Qunping, An Qiaoshi, Lin Yuanbao, Energy & environmental science . 2020,第12期

机译：超过14％的效率通过低带隙聚合物受体使能量效率为低能量损失和有效的电荷分离
5. Low-bandgap conjugated polymers based on alkylthiothienyl-substituted benzodithiophene for efficient bulk heterojunction polymer solar cells [J] . Wang Xunchang, Tong Jinhui, Guo Pengzhi, Polymer: The International Journal for the Science and Technology of Polymers . 2017,第期

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6. Kinetic Monte Carlo modeling of low-bandgap polymer solar cells [C] . Albes Tim, Popescu Bogdan, Popescu Dan, IEEE Photovoltaic Specialists Conference . 2014

机译：低带隙聚合物太阳能电池的动力学蒙特卡洛模拟
7. High energy density, and low loss polymer dielectrics for energy storage capacitors and organic electronics. [D] . Wu, Shan. 2014

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8. PNAS Plus: Closely packed low reorganization energy π-extended postfullerene acceptors for efficient polymer solar cells [O] . Steven M. Swick, Weigang Zhu, Micaela Matta, 2018

机译：PNAS Plus：紧密包装低重组能量π-扩展的富勒烯后受体用于高效聚合物太阳能电池
9. Bandgap and Molecular Level Control of the Low-Bandgap Polymers Based on 3,6-Dithiophen-2-yl-2,5-dihydropyrrolo3,4-cpyrrole-1,4-dione toward Highly Efficient Polymer Solar Cells [O] . Lijun Huo, Jianhui Hou, Hsiang-yu Chen, 2009

机译：基于3,6-二硫代-2-基-2,5-二氢吡咯并3,4-c吡咯-1,4-二酮的低带隙聚合物对高效聚合物太阳能电池的带隙和分子水平控制
10. Highly Crystalline and Low Bandgap Donor Polymers for Efficient Polymer Solar Cells. [R] . Liu, J., Choi, H., Kim, J. Y., 2012

机译：用于高效聚合物太阳能电池的高结晶和低带隙供体聚合物。

Low-Bandgap DPP-Based Quinoxaline with Extended EQE and Low Energy Loss for Efficient Polymer Solar Cells

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