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Dependency of Ag wetting on the oxygen nonstoichiometry of oxide surfaces

Experimental and numerical evidence support that both extremely oxygen-deficient and oxygen-excessive ZnO surfaces increase Ag wetting during the inceptive clustering stages, without any favorable contribution in hastening the development of continuous Ag layers. [Display omitted] •Solid evidence su...

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Bibliographic Details
Published in:Applied surface science 2023-02, Vol.611, p.155699, Article 155699
Main Authors: Jeong, Eunwook, Lee, Sang-Geul, Yu, Seung Min, Bae, Jong-Seong, Han, Seung Zeon, Lee, Gun-Hwan, Choi, Eun-Ae, Yun, Jungheum
Format: Article
Language:English
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Summary:Experimental and numerical evidence support that both extremely oxygen-deficient and oxygen-excessive ZnO surfaces increase Ag wetting during the inceptive clustering stages, without any favorable contribution in hastening the development of continuous Ag layers. [Display omitted] •Solid evidence supports good Ag wetting on nonstoichiometric ZnO surfaces.•Ionic damage-free techniques provide highly divergent ZnO nonstoichiometric levels.•Both extreme O deficiency and O excess increase Ag adhesion on ZnO surfaces.•Intensified nonstoichiometry accelerates a resistivity decrease in Ag layers.•Intensified nonstoichiometry, however, induces pinhole formation in Ag layers. Oxide substrates are frequently modified to have either an oxygen deficiency or excess to synthesize a completely continuous, ultrathin metal layer on them by strengthening the metal–oxide adhesion. However, conventional surface treatments using ionic irradiation inevitably induce detrimental structural irregularities, along with chemical modification, on the surface of oxide substrates. This study explores the dependency of Ag wetting on the oxygen deficiency and excess on the surface of a ZnO substrate. The favorable contribution of the increased oxygen deficiency and excess of ZnO surfaces in improving Ag wetting during the inceptive growth stages is evidenced by both experimental results and numerical interpretations. This improved Ag wetting is attributed to a significant reduction in free energy at the Ag–ZnO interfaces, whereas pinholes remain in thicker Ag layers on the ZnO surfaces. This finding extends earlier studies, reporting a favorable role of an increased oxygen deficiency on Ag wetting, with the point that oxygen excess beyond a threshold value is also helpful in improving Ag wetting. Our findings redefine the underlying Ag wetting mechanisms of the nonstoichiometric surface of oxide substrates. Moreover, the study provides guidelines for implementing a continuous ultrathin Ag layer while avoiding ion-induced damage to the oxide substrates.
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2022.155699