揭示包晶体薄膜滞后的异质性。

0 MATERIALS SCIENCE, MULTIDISCIPLINARY
Zhouyiao Zou, Haian Qiu, Zhibin Shao
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引用次数: 0

摘要

在基于包晶石的光电设备中观察到的电流-电压滞后现象是一个关键问题,它使设备参数的准确评估变得复杂,从而影响了设备的性能和适用性。尽管研究人员为破译磁滞的起源做出了大量努力,但其根本原因仍是一个颇具争议的话题。通过采用纳米尺度的研究来阐明滞后与形态特征之间的关系,本研究详细探讨了包晶体光电器件中纳米尺度的光电流-电压滞后。通过对局部 I-V 曲线阵列的细致分析,我们的研究确定了两个主要的滞后描述因子,在 87% 的受检位置发现了主要的反向滞后模式。这种模式主要归因于探针与包晶材料之间的界面所遇到的能量障碍。我们的研究结果强调了磁滞行为中固有的明显异质性和随晶粒而变化的特性,平均磁滞指数值为 0.24。调查表明,局部磁滞现象不能完全归因于光电荷收集过程或晶界的有机阳离子迁移。相反,它似乎受到局部表面陷阱态的重要影响,而陷阱态在调节电子和空穴电流动力学方面起着关键作用。通过确定造成磁滞的关键因素,如局部表面陷阱态及其对电子和空穴电流动力学的影响,我们的研究结果为采取有针对性的策略减轻这些影响铺平了道路。这包括开发新型材料和器件架构,旨在最大限度地减少能量障碍和提高电荷载流子迁移率,从而提高器件性能和寿命。在理解滞后的微观机制方面取得的这一突破强调了表面/界面缺陷阱钝化在减轻滞后效应方面的极端重要性,为提高过氧化物太阳能电池的性能提供了新的途径。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Unveiling heterogeneity of hysteresis in perovskite thin films.

Unveiling heterogeneity of hysteresis in perovskite thin films.

The phenomenon of current-voltage hysteresis observed in perovskite-based optoelectronic devices is a critical issue that complicates the accurate assessment of device parameters, thereby impacting performance and applicability. Despite extensive research efforts aimed at deciphering the origins of hysteresis, its underlying causes remain a subject of considerable debate. By employing nanoscale investigations to elucidate the relationship between hysteresis and morphological characteristics, this study offers a detailed exploration of photocurrent-voltage hysteresis at the nanoscale within perovskite optoelectronic devices. Through the meticulous analysis of localized I-V curve arrays, our research identifies two principal hysteresis descriptors, uncovering a predominantly inverted hysteresis pattern in 87% of the locations examined. This pattern is primarily attributed to the energetic barrier encountered at the interface between the probe and the perovskite material. Our findings underscore the pronounced heterogeneity and grain-dependent variability inherent in hysteresis behavior, evidenced by an average Hysteresis Index value of 0.24. The investigation suggests that the localized hysteresis phenomena cannot be exclusively attributed to either photocharge collection processes or organic cation migration at grain boundaries. Instead, it appears significantly influenced by localized surface trap states, which play a pivotal role in modulating electron and hole current dynamics. By identifying the key factors contributing to hysteresis, such as localized surface trap states and their influence on electron and hole current dynamics, our findings pave the way for targeted strategies to mitigate these effects. This includes the development of novel materials and device architectures designed to minimize energy barriers and enhance charge carrier mobility, thereby improving device performance and longevity. This breakthrough in understanding the microscale mechanisms of hysteresis underscores the critical importance of surface/interface defect trap passivation in mitigating hysteretic effects, offering new pathways for enhancing the performance of perovskite solar cells.

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