Prolonged mechanical dynamics via imide bridged ZnO composites for fast response flexible photo-electronics

IF 6.9 2区材料科学 Q2 CHEMISTRY, PHYSICAL

Applied Surface Science Pub Date : 2025-04-05 DOI:10.1016/j.apsusc.2025.163170

Jihyun Lim , Woongsik Jang , Jin Young Kim , Dong Hwan Wang

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Abstract

In this study, we incorporate a promising small molecule—n-type perylene diimide derivative (NPDI)—into widely used ZnO nanoparticles (NPs) as the electron transport layer, which effectively controls interface defects and leads to significant improvements in the performance and mechanical durability of organic optoelectronic devices. Conventional ZnO NP systems suffer from defects caused by oxygen vacancies at the interface with the Ag electrode in a single-layer configuration, which hinder charge transport and mechanical stress resistance. When the ZnO/NPDI bilayer is introduced, the defects in ZnO are smoothed and bonded, forming a durable passivation layer that inhibits charge recombination and enhances the mechanical properties of flexible devices. Moreover, the ZnO/NPDI bilayer forms an ohmic contact with the Ag electrode while simultaneously enhancing the hole injection barrier, facilitating smooth charge transport and effective dark current suppression. Accordingly, ZnO/NPDI-based flexible organic devices exhibit reduced internal resistance and enhanced stability under bending stresses due to successful interface optimization.

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亚胺桥接ZnO复合材料用于快速响应柔性光电子学

在这项研究中，我们将一种有前途的小分子n型苝二亚胺衍生物（NPDI）作为电子传输层加入到广泛使用的ZnO纳米颗粒（NPs）中，有效地控制了界面缺陷，并显著提高了有机光电器件的性能和机械耐久性。传统的ZnO NP体系在与Ag电极的单层结构中存在氧空位导致的缺陷，这阻碍了电荷传输和机械应力抵抗。当引入ZnO/NPDI双分子层时，ZnO中的缺陷被平滑粘合，形成持久的钝化层，抑制电荷复合，提高柔性器件的力学性能。此外，ZnO/NPDI双分子层与Ag电极形成欧姆接触，同时增强了空穴注入势垒，促进了平滑的电荷传输和有效的暗电流抑制。因此，基于ZnO/ npdi的柔性有机器件由于成功的界面优化，在弯曲应力下表现出更低的内阻和更高的稳定性。

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来源期刊

Applied Surface Science 工程技术-材料科学：膜

CiteScore

12.50

自引率

7.50%

发文量

3393

审稿时长

67 days

期刊介绍： Applied Surface Science covers topics contributing to a better understanding of surfaces, interfaces, nanostructures and their applications. The journal is concerned with scientific research on the atomic and molecular level of material properties determined with specific surface analytical techniques and/or computational methods, as well as the processing of such structures.