Dry Transfer Printed Hole Transport Layer for Hysteresis-Free Colloidal Quantum Dot Solar Cells

IF 5.3 3区 工程技术 Q1 ENGINEERING, MANUFACTURING
Hyung Cheoul Shim, Jung Hoon Song, Areum Kim, Hye-Mi So, Seungmin Hyun, Sohee Jeong
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Abstract

Colloidal quantum dot (CQD) solar cells have drawn a lot of attention because of their potential for bandgap engineering, which enables broad and powerful absorption in the wavelength of sunlight, and low-cost process based on the solution phase production. However, the interfacial problems resulting from the heterojunction structure containing electron and hole transport layers cause a hysteresis phenomenon that weakens the device stability. We used the dry-transfer technique to implement a hole transport layer (HTL) with enhanced interfacial properties in devices. This approach is highly reproducible and allows for precise thickness control of the HTL. It also uses substantially less environmentally harmful organic solvents for the ligand exchange process than those required by the previous layer-by-layer (LbL) deposition technique. Additionally, about 400 nm thick CQD film could be deposited without the ligand exchange process, and a power conversion efficiency of 10% with minimized hysteresis was achieved using this method. Moreover, by improving the interfacial properties over the traditional LbL approach, it was feasible to lower the charge transfer resistance related to the device's hysteresis by a factor of up to four or more.

Abstract Image

用于无滞后胶体量子点太阳能电池的干转移印制空穴传输层
胶体量子点(CQD)太阳能电池具有带隙工程的潜力,可实现对太阳光波长的广泛而强大的吸收,而且基于溶液相生产的工艺成本低,因此备受关注。然而,包含电子和空穴传输层的异质结结构所产生的界面问题会导致滞后现象,从而削弱器件的稳定性。我们采用干法转移技术在器件中实现了具有增强界面特性的空穴传输层(HTL)。这种方法具有很高的可重复性,可以精确控制 HTL 的厚度。与之前的逐层(LbL)沉积技术相比,它还大大减少了配体交换过程中对环境有害的有机溶剂的使用。此外,无需配体交换过程就能沉积约 400 nm 厚的 CQD 薄膜,并利用这种方法实现了 10% 的功率转换效率,同时将滞后现象降至最低。此外,与传统的 LbL 方法相比,通过改善界面特性,可以将与器件滞后有关的电荷转移电阻降低四倍或更多。
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来源期刊
CiteScore
10.30
自引率
9.50%
发文量
65
审稿时长
5.3 months
期刊介绍: Green Technology aspects of precision engineering and manufacturing are becoming ever more important in current and future technologies. New knowledge in this field will aid in the advancement of various technologies that are needed to gain industrial competitiveness. To this end IJPEM - Green Technology aims to disseminate relevant developments and applied research works of high quality to the international community through efficient and rapid publication. IJPEM - Green Technology covers novel research contributions in all aspects of "Green" precision engineering and manufacturing.
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