Determination of the dielectric constant of non-planar nanostructures and single nanoparticles by electrostatic force microscopy

IF 1.1 Q3 PHYSICS, MULTIDISCIPLINARY Journal of Physics Communications Pub Date : 2022-12-01 DOI:10.1088/2399-6528/aca87b
Marco Fuhrmann, A. Musyanovych, R. Thoelen, Hildegard Moebius
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引用次数: 1

Abstract

Electrostatic Force Microscopy has been proven to be a precise and versatile tool to perform quantitative measurements of the dielectric constant of thin film domains in the nanometer range. However, it is difficult to measure non-planar nanostructures because topographic crosstalk significantly contributes to the measured signal. This topographic crosstalk due to distance changes between tip and substrate measuring non-planar surface structures is still an ongoing issue in literature and falsifies measurements of the dielectric constant of nanostructures and nanoparticles. Tip and substrate form a capacitor based on the contact potential difference between the tip and substrate material. An increase of the distance between tip and substrate causes a repulsive force while a decrease causes an attractive force. Thus, measuring in the so-called lift mode scanning the surface in a second scan following the topography determined by a first scan leads to a mirroring of the non-planar surface structure in the electrostatic signal superimposing the signal from dielectric contrast. In this work we demonstrate that the topographic crosstalk can be avoided by using the linear mode instead of the lift mode. The use of the linear mode now allows the determination of the dielectric constant of single nanoparticles.
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静电力显微镜测定非平面纳米结构和单个纳米颗粒的介电常数
静电力显微镜已被证明是一种精确而通用的工具,可以对纳米范围内的薄膜畴的介电常数进行定量测量。然而,测量非平面纳米结构是困难的,因为形貌串扰对测量信号有显著贡献。这种由测量非平面表面结构的尖端和基底之间的距离变化引起的地形串扰在文献中仍然是一个持续存在的问题,并且伪造了纳米结构和纳米颗粒的介电常数的测量。尖端和衬底基于尖端和衬底材料之间的接触电势差形成电容器。尖端和基底之间距离的增加引起排斥力,而减小引起吸引力。因此,在所谓的提升模式中进行测量,在遵循由第一扫描确定的形貌的第二扫描中扫描表面,导致静电信号中的非平面表面结构的镜像,该静电信号叠加来自介电对比度的信号。在这项工作中,我们证明了使用线性模式而不是升力模式可以避免地形串扰。线性模式的使用现在允许确定单个纳米颗粒的介电常数。
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来源期刊
Journal of Physics Communications
Journal of Physics Communications PHYSICS, MULTIDISCIPLINARY-
CiteScore
2.60
自引率
0.00%
发文量
114
审稿时长
10 weeks
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