Enhanced high-energy proton radiation hardness of ZnO thin-film transistors with a passivation layer

IF 13.4 2区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Nano Convergence Pub Date : 2025-01-30 DOI:10.1186/s40580-025-00474-5

Yongsu Lee, Hae-Won Lee, Su Jin Kim, Jeong Min Park, Byoung Hun Lee, Chang Goo Kang

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引用次数: 0

Abstract

Metal-oxide thin-film semiconductors have been highlighted as next-generation space semiconductors owing to their excellent radiation hardness based on their dimensional advantages of very low thickness and insensitivity to crystal structure. However, thin-film transistors (TFTs) do not exhibit intrinsic radiation hardness owing to the chemical reactions at the interface exposed to ambient air. In this study, significantly enhanced radiation hardness of Al₂O₃-passivated ZnO TFTs against high-energy protons with energies of up to 100 MeV is obtained owing to the passivation layer blocking interactions with external reactants, thereby maintaining the chemical stability of the thin-film semiconductor. These results highlight the potential of passivated metal-oxide thin films for developing reliable radiation-hardened semiconductor devices that can be used in harsh space environments. In addition, the relationship between low-frequency noise and defects due to oxygen vacancies was revealed, which can be utilized to improve device reliability.

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钝化层增强ZnO薄膜晶体管的高能质子辐射硬度。

金属氧化物薄膜半导体由于其极低的厚度和对晶体结构不敏感的尺寸优势而具有优异的辐射硬度，已成为下一代空间半导体。然而，薄膜晶体管（TFTs）由于暴露在环境空气中的界面处的化学反应而不表现出固有的辐射硬度。在本研究中，由于钝化层阻断了与外界反应物的相互作用，al2o3钝化ZnO tft对能量高达100 MeV的高能质子的辐射硬度得到了显著提高，从而保持了薄膜半导体的化学稳定性。这些结果突出了钝化金属氧化物薄膜在开发可靠的辐射硬化半导体器件方面的潜力，这些器件可用于恶劣的空间环境。此外，还揭示了低频噪声与氧空位缺陷之间的关系，可用于提高器件的可靠性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Nano Convergence Engineering-General Engineering

CiteScore

15.90

自引率

2.60%

发文量

审稿时长

13 weeks

期刊介绍： Nano Convergence is an internationally recognized, peer-reviewed, and interdisciplinary journal designed to foster effective communication among scientists spanning diverse research areas closely aligned with nanoscience and nanotechnology. Dedicated to encouraging the convergence of technologies across the nano- to microscopic scale, the journal aims to unveil novel scientific domains and cultivate fresh research prospects. Operating on a single-blind peer-review system, Nano Convergence ensures transparency in the review process, with reviewers cognizant of authors' names and affiliations while maintaining anonymity in the feedback provided to authors.