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引用次数: 0
摘要
采用超声原子力显微镜(ultrasound - Atomic Force Microscopy, afm)对纳米薄膜体系中超薄涂层的力学性能进行了表征。采用修正赫兹理论对超薄涂层的动态特性进行了精确的理论分析。采用直流磁控溅射法制备了厚度为200nm的铝和钛薄膜。当悬臂顶端接近并与样品表面耦合时,相互作用力和边界条件随样品接触刚度的变化而变化。因此,振动悬臂梁的接触共振频率随局部接触刚度的变化而变化。研究表明,超声-原子力显微镜是一种有潜力的非破坏性表征超薄涂层力学性能的技术。
Analysis of dynamic characteristic for ultra-thin coating layer with Ultrasonic Atomic Force Microscopy
Ultrasonic Atomic Force Microscopy (Ultrasonic-AFM) was applied to characterize the mechanical properties of an ultra-thin coating layer in a nanoscale thin film system. The modified Hertzian theory was adopted for accurate theoretical analysis of the dynamic characteristics of the ultra-thin coating layer. Aluminum and Titanium thin films with 200 nm thickness were coated on the substrate using the DC Magnetron sputtering method. When the cantilever tip approaches and couples with a sample surface, the interaction forces and boundary conditions change in response to the sample contact stiffness. As a result, the contact resonance frequency of the vibrating cantilever shifts according to the local contact stiffness. This research demonstrates that Ultrasonic-AFM is a potential technique for nondestructively characterizing the mechanical properties of the ultra-thin coating layer.
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