钝化效应对氧化锌:铝结构紫外线探测性能的影响

Rajat Nagpal, Maxim Chiriac, Alexandr Sereacov, A. Birnaz, N. Ababii, C. Lupan, A. Buzdugan, Iulia Sandu, Leonard Siebert, Thierry Pauporté, O. Lupan
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引用次数: 0

摘要

本研究旨在开发低功率、高选择性的紫外线传感器,以连续监测个性化的紫外线照射,并研究退火对传感器紫外线检测特性的影响。研究样品在退火前/后对 370 纳米紫外线辐射的最大紫外线响应分别为 620/488(25°C/50°C)。传感器的热退火(250 °C,1 小时)使其在 25 °C时的下降时间从 3860 秒缩短到 262 秒,在 75 °C的工作温度下,370 纳米波长的响应率最高(约 48 mA/W)。因此,对 370 纳米紫外线照明的出色选择性可归因于热退火效应,它增加了传感薄膜的结晶度、晶粒尺寸和粗糙度。PL 测量结果表明,由于薄膜中铝含量的存在,结构缺陷被抑制,退火后强度增加,紫外线响应增强。总之,这些结构在额外的热退火之前,尤其是退火之后,都表现出了卓越的紫外线特性。这种基于纳米材料的传感器的紫外线传感机理可以用这些结构表面发生的物理化学过程来解释。基于 ZnO:Al 薄膜的器件在退火后获得的结果优于其他纳米结构的性能,证明了在不同工作温度下紫外线传感应用在各个领域的新成果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
ANNEALING EFFECT ON UV DETECTION PROPERTIES OF ZnO:Al STRUCTURES
The aim of this study was to develop low-powered, highly selective UV sensor to continuously monitor personalized UV exposure as well as to study annealing effect on UV detection properties of the sensors. ZnO:Al structures were obtained by chemical growth method followed by thermal annealing at 625 °C for 2 h. The studied samples exhibit maximal UV response of 620/488 at 25 °C/50 °C to 370 nm UV radiation before/after annealing, respectively. Thermal annealing of sensor (250 °C for 1 h) led to improvement in fall time from 3860 seconds to 262 seconds at 25 °C and highest responsivity (~48 mA/W) came out for 370 nm wavelength at 75 °C operating temperatures. Consequently, excellent selectivity for 370 nm UV illumination can be ascribed as due to thermal annealing effect which increases the crystallinity, grain size, and roughness of the sensing film. The PL measurements reveals the suppression of structural defects, increase in intensity after annealing and enhanced UV response due to presence of Al content in films. Overall, these structures showed magnificent UV properties, before and especially after additional thermal annealing. UV sensing mechanism of such nanomaterial-based sensor were explained with physio-chemical processes take place on the surface of these structures. The obtained results on annealed ZnO:Al films-based devices is superior to reported performances of other nanostructures, proving new results for UV sensing applications at different operating temperatures in various fields.
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