Nanomechanical properties of polycrystalline vanadium oxide thin films of different phase composition

P.M. Lytvyn, V. Dzhagan, M. Valakh, A.A. Korchovyi, O.F. Isaieva, O.A. Stadnik, O. Kulbachynskyi, O.Yo. Gudymenko, B. Romanyuk, V.P. Melnik
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Abstract

Vanadium oxide (VO x ) thin films are promising materials, exhibiting electrical, optical, and mechanical properties highly tunable by processing and structure. This work uniquely applying atomic force microscopy (AFM) nanoindentation correlated with X-ray diffractometry and Raman spectroscopy structural analysis to investigate the intricate connections between VO x post-annealing, phase composition, and resulting nanoscale mechanical functionality. Utilizing an ultra-sharp diamond tip as a nanoscale indenter, indentation is performed on VO x films with systematic variations in structure – from mixed insulating oxides to VO 2 -dominated films. Analytical modeling enables extraction of hardness and elastic modulus with nanoscale resolution. Dramatic mechanical property variations are observed between compositions, with order-of-magnitude increases in hardness and elastic modulus for the VO 2 -rich films versus insulating oxides. Ion implantation further enhances nanomechanical performance through targeted defect engineering. Correlating indentation-derived trends with detailed structural and morphological characterization elucidates explicit structure-property relationships inaccessible by other techniques. The approach provides critical mechanics-driven insights into links between VO x synthesis, structure evolution, and property development. Broader implementation will accelerate processing optimization for electronics and advanced fundamental understanding of nanoscale structure-functionality relationships
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不同相组成的多晶氧化钒薄膜的纳米力学性能
氧化钒(VO x)薄膜是一种很有前途的材料,具有高度可调的电学、光学和机械性能。这项工作独特地应用原子力显微镜(AFM)纳米压痕与x射线衍射和拉曼光谱结构分析相结合,研究了VO x退火后,相组成和纳米级机械功能之间的复杂联系。利用超锋利的金刚石尖端作为纳米级压痕器,在具有系统结构变化的VO x薄膜上进行压痕-从混合绝缘氧化物到VO 2主导的薄膜。解析建模使硬度和弹性模量的提取与纳米级的分辨率。在不同成分之间观察到显著的机械性能变化,与绝缘氧化物相比,富含VO 2的薄膜的硬度和弹性模量增加了数量级。离子注入通过靶向缺陷工程进一步提高纳米力学性能。将压痕衍生的趋势与详细的结构和形态特征相关联,阐明了其他技术无法实现的明确的结构-性质关系。该方法为VO x合成、结构演变和属性开发之间的联系提供了关键的力学驱动见解。更广泛的实施将加速电子工艺的优化,并提高对纳米结构-功能关系的基本理解
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